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MORAVA K-THEORY AND FILTRATIONS BY POWERS

Published online by Cambridge University Press:  04 July 2023

Tobias Barthel
Affiliation:
Max Planck Institute for Mathematics, Vivatsgasse 7, 53111 Bonn, Germany ([email protected])
Piotr Pstrągowski*
Affiliation:
Department of Mathematics, Harvard University, 1 Oxford Street, Cambridge, MA 02139, USA
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Abstract

We prove the convergence of the Adams spectral sequence based on Morava K-theory and relate it to the filtration by powers of the maximal ideal in the Lubin–Tate ring through a Miller square. We use the filtration by powers to construct a spectral sequence relating the homology of the K-local sphere to derived functors of completion and express the latter as cohomology of the Morava stabiliser group. As an application, we compute the zeroth limit at all primes and heights.

Type
Research Article
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Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (https://creativecommons.org/licenses/by/4.0), which permits unrestricted re-use, distribution and reproduction, provided the original article is properly cited.
Copyright
© The Author(s), 2023. Published by Cambridge University Press

1 Introduction

In this paper, which consists of three closely related parts, we investigate the relationship between the filtration by powers of the maximal ideal in the Lubin–Tate ring and chromatic homotopy theory from several perspectives. In the first part, we focus on Morava K-theories and their associated Hopf algebroids. In particular, we give an invariant description of their cohomology and prove its finiteness. We then establish convergence of the K-based Adams spectral sequence and relate it to the K-local Adams–Novikov and filtration by powers spectral sequences through a Miller square, and describe it completely at large enough primes. In the last part, we construct Hopkins’s spectral sequence relating homology of the K-local sphere with derived functors of completion, and identify the latter with cohomology of the Morava stabiliser group. As an application, we compute the zeroth limit at all primes and heights.

Main results

A classical approach to the study of an arithmetic problem is to first consider its reduction to residue fields, and to then reassemble the local solutions. Over the p-local integers, there are just two reside fields, namely, the field $\mathbb {Q}$ of rational numbers and the finite field $\mathbb {F}_p$ corresponding to the closed point. Informally, these detect, respectively, the torsion-free and torsion phenomena.

The approach of reducing to residue fields also works very well in stable homotopy theory, where one is interested in classifying stable homotopy classes of maps between finite complexes. Identifying a classical field k with the corresponding Eilenberg–MacLane spectrum, we have a descent spectral sequence of signature

(1.1) $$ \begin{align} E_2^{s,t}\simeq \operatorname{\mathrm{Ext}}_{\pi_*(k \otimes_{S^0} k)}^{s,t}(k, k) \implies \pi_{t-s}(S^0_{k}), \end{align} $$

where $S^{0}_{k}$ is the appropriate Bousfield localisation. When $k = \mathbb {Q}$ , this collapses immediately, recovering Serre’s calculation that $\pi _{*} S^{0} \otimes _{\mathbb {Z}} \mathbb {Q} \simeq \mathbb {Q}$ . The situation is much more complicated when $k = \mathbb {F}_{p}$ , in which case, ${\mathcal {A}}_* = \pi _*(\mathbb {F}_p\otimes _{S^0}\mathbb {F}_p)$ is the dual Steenrod algebra and the above recovers the classical Adams spectral sequence. In this case, the spectral sequence converges completely, but it does not collapse at any finite page, and there is no known algorithmic way of understanding its structureFootnote 1 . It is arguably the most important tool for computing the stable homotopy groups of spheres.

A new feature in homotopy theory which is not visible in the algebraic contexts is that, even p-locally, $\mathbb {Q}$ and $\mathbb {F}_p$ are not the only residue fields of spectra. Instead, we have an infinite family of prime fields of ‘intermediate characteristic’, given by the Morava K-theories [Reference Hovey and StricklandHS99]. These are homotopy ring spectra K with the properties that

  1. (1) $\pi _{*} K \simeq k [u^{\pm 1}]$ , where k is a perfect field of characteristic p and u is an invertible variable of degree $|u| = 2$ and

  2. (2) the Quillen formal group over k is of height $0 < n < \infty $ .

One can show that such a homotopy ring spectrum exists for any $\textbf {G}_{0}$ of finite height over a perfect field. By a celebrated result of Devinatz, Hopkins and Smith [Reference Devinatz, Hopkins and SmithDHS88], [Reference Hopkins and SmithHS98], together with $\mathbb {Q}$ and $\mathbb {F}_p$ , these are the only residue fields of p-local spectra.

Morava K-theories are very calculable for at least two distinct reasons:

  1. (1) the coefficients $K_{*}$ form a graded field, so that we have an unrestricted Künneth isomorphism $K_{*}(X \otimes Y) \simeq K_{*}(X) \otimes _{K_{*}} K_{*}(Y)$ for any $X, Y$ ;

  2. (2) there’s a canonical Poincare duality isomorphism $K_{*}(X) \simeq K^{*}(X)$ whenever X is a $\pi $ -finite space, in particular, a classifying space of a finite group.

The second property, known as ambidexterity, is one way in which Morava K-theories behave as if they were of characteristic zero, despite the coefficients $K_{*}$ being of positive characteristic. This surprising feature makes Morava K-theories a powerful tool also in more geometric contexts, such as in the breakthrough work of Abouzaid and Blumberg on the Arnold conjecture in symplectic topology [Reference Abouzaid and BlumbergAB21].

In the present paper, we set up and analyse the descent spectral sequence associated to the Morava K-theories. As a first result, we verify that we indeed do have convergence.

Theorem A (7.4, 7.5).

Let K be a Morava K-theory. The K-based Adams spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Ext}}^{s, t}_{K_{*}K}(K_*,K_*(X)) \implies \pi_{t-s}L_{K}X \end{align*}$$

is conditionally convergent for any spectrum X and converges completely whenever X is K-locally dualisable.

Note that this spectral sequence does not, in general, have a horizontal vanishing line at any finite page: while each group on the second page of this spectral sequence for the sphere is torsion, the abutment $\pi _*L_{K}S^0$ is known to contain torsion-free summands. In order to establish conditional convergence, we instead reduce to the case of a finite n complex, where such vanishing lines exist. Complete convergence is the consequence of the degreewise finiteness of the $E_{2}$ -term, which we prove for dualisable spectra using the Cartan–Eilenberg spectral sequence. Going back to the case of nonlocalised spectra, the utility of the classical Adams spectral sequence based on $\mathbb {F}_{p}$ is further amplified when coupled with the Adams–Novikov spectral sequence, which is the descent spectral sequence based on the Brown–Peterson spectrum $BP$ . As one spectacular application, Miller constructs a square relating the two spectral sequences and compares the differentials to compute the $v_1$ -periodic homotopy of Moore spaces, thereby proving the telescope conjecture at height 1 and for all odd primes [Reference MillerMil81].

The situation is similar in the case of the K-based Adams, which has a cousin which might be more familiar to the working chromatic homotopy theorist, namely, the K-local $E_n$ -based Adams spectral sequence. Here, $E_n$ denotes the Lubin–Tate spectrum associated to the formal group $\mathbf {G}_{0}$ , parametrising derived deformations of the latter. We show that the relation between the two spectral sequences is again governed by a square of spectral sequences of the following explicit form.

Theorem B (8.8, 8.11).

The K-local Miller square associated to $(E,K)$ is of the form

where the May spectral sequence is obtained from the $\mathfrak {m}$ -adic filtration of $E_{*}^{\vee }X$ .

We also identify the Mahowald spectral sequence in the square above with a Cartan–Eilenberg spectral sequence of a certain extension of Hopf algebroids canonically attached to each Morava K-theory (see Section 8 for details). A theorem of Miller relates the $d_{2}$ -differentials in the K-Adams and May spectral sequences, but at large primes, we can say much more. If $2p - 2> n^{2}+n$ , then it is well-known that the K-local E-based Adams spectral sequence for the sphere collapses at the second page. Using a variation on the classical argument of Milnor, we equip $K_{*}K$ at odd primes with an additional grading which also forces the collapse of the Mahowald spectral sequence.

It follows that at sufficiently large primes, two of the spectral sequences in Miller’s square collapse, and it is thus natural to expect that the other two can be identified. This is indeed the case, as we show the following.

Theorem C (9.23).

If $2p-2> n^{2}+n+1$ , then the K-based Adams spectral sequence for $S^{0}_{K}$ can be given an additional grading so that it becomes isomorphic to the May spectral sequence

(1.2) $$ \begin{align} \operatorname{\mathrm{Ext}}_{E_{*}^{\vee}E}(E_{*}, \bigoplus_k \mathfrak{m}^{k}/\mathfrak{m}^{k+1} E_{*}) \implies \operatorname{\mathrm{Ext}}_{E_{*}^{\vee}E}(E_{*}, E_{*}) \end{align} $$

induced by the filtration of $E_{*}$ by the powers of the maximal ideal.

Note that one new major phenomenon in intermediate characteristic is that Morava K-theories do depend on choices; in particular, on the choice of a formal group. By a result of Lazard Using a variation, any two such formal groups of the same height are isomorphic over the separable closure; it follows that for our purposes, all Morava K-theories of the same height are essentially interchangeable, in particular, they determine the same Adams spectral sequence.

To be more precise, while the Hopf algebroid $K_{*}K$ depends on the choice of a Morava K-theory, its category of comodules does not, by a result of Hovey and Strickland [Reference Hovey and StricklandHS05a]. In the body of the text, we describe a different derivation of this result, identifying the category of $K_{*}K$ -comodules with the category $\operatorname {\mathrm {Mil}}_{abs}$ of absolute Milnor modules, which are certain sheaves on finite spectra (see Section 4). This gives an approach to the Adams spectral sequence based on Morava K-theory, which only depends on the prime and the height but no other choices.

On a different note, the completion tower of comodules of the form

$$\begin{align*}\ldots \rightarrow E_{*}/\mathfrak{m}^{3} \rightarrow E_{*}/\mathfrak{m}^{2} \rightarrow E_{*}/ \mathfrak{m} \end{align*}$$

appearing in Theorem C also leads to a another spectral sequence, first studied by Hopkins and SadofskyFootnote 2 . The latter spectral sequence approaches the transchromatic information contained in $L_{K}S^0$ through its uncompleted E-homology $E_*(L_{K}S^0)$ , as opposed to the homotopy groups, as we now describe in more detail.

To provide some context, recall that it is known that at large primes there exists an equivalence between the homotopy categories of E-local spectra and differential comodules. Under this equivalence, the limit $\varprojlim E_{*} / \mathfrak {m}^{k}$ in the derived $\infty $ -category corresponds to the K-local sphere $S^{0}_{K}$ [Reference PstragowskiPst18]; thus, the derived completion of $E_{*}$ can be thought of as the algebraic analogue of the K-local sphere.

At smaller primes, we do not have algebraic models for the homotopy category, but we instead have a spectral sequence relating the homology groups of the derived completion to $E_{*} (S^{0}_{K})$ . This spectral sequence, originally due to Hopkins and Sadofsky, was subsequently worked out by Peterson [Reference PetersonPet20], adapting the classical construction of the Adams spectral sequence. We follow a slightly different approach, based on the notion of an adapted homology theory and Devinatz–Hopkins’s modified Adams spectral sequence [Reference DevinatzDev97].

Our construction is closely related to the work of Hovey on derived products of comodules [Reference HoveyHov07], and, in fact, works in much greater generality (see Section 11). In the case of E-homology, we are able to express these derived limits as cohomology of the Morava stabiliser group, leading to the following statement.

Theorem D (11.14, 12.14, 12.12).

Let be the uncompleted E-homology of itself, given the unique topology which restricts to the $\mathfrak {m}$ -adic topology on each finitely generated $E_{*}$ -submodule. Then, there exists a canonical isomorphism

$$\begin{align*}\mathrm{H}^{s}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, E_{t}E) \simeq (\textstyle\varprojlim_{E_{*}E}^{s} E_{*}/\mathfrak{m}^{k})_{t} \end{align*}$$

between the continuous cohomology of the Morava stabiliser group and the derived functors of the limit in $E_{*}E$ -comodules. Moreover, there exists a spectral sequence of $E_*E$ -comodules of the form

(1.3) $$ \begin{align} E_2^{s,t} \simeq \mathrm{H}^{s}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, E_{t}E) \implies E_{t-s}(L_{K}S^0) \end{align} $$

with differentials $d_r^{s,t}\colon E_r^{s,t} \to E_r^{s+r,t+r-1}$ . This spectral sequence converges completely and collapses at a finite page with a horizontal vanishing line.

The subtle point in this result is the convergence of the spectral sequence, which relies crucially on the finite virtual cohomological dimension of the Morava stabiliser group. Note that here it is important to consider the derived sequential limits in the category of comodules as opposed to ordinary modules over $E_*$ ; indeed, in positive degrees, the latter all vanish in this case, and there would be no hope of having a convergent spectral sequence.

The above spectral sequence underlies one approach towards Hopkins’s chromatic splitting conjecture [Reference PetersonPet], [Reference HoveyHov95]. In a nutshell, the latter provides a precise description of the transchromatic behaviour of the K-local sphere; that is, its behaviour under applying chromatic localisations $L_h$ for intermediate heights $0 \le h <n$ . As such, it has been verified for all heights $n \le 2$ and all primes [Reference Shimomura and YabeSY95, Reference Goerss, Henn and MahowaldGHM12, Reference BeaudryBea17], with a minor modification to the original prediction at $n=p=2$ ([Reference Beaudry, Goerss and HennBGH17]). Beyond height 2, the conjecture remains wide open.

The standard way of approaching the splitting conjecture is through an explicit computation of the homotopy groups of $L_{K}S^0$ . However, as mentioned, its transchromatic information is also encoded in the uncompleted E-homology, and this is what the spectral sequence (11.15) abuts to.

Using the identification of derived functors of the limit with continuous cohomology of the Morava stabiliser group, we are able to compute the zeroth limit at all primes and heights.

Theorem E (14.13).

There is a canonical isomorphism

$$\begin{align*}\textstyle\varprojlim_{E_{*}E} E_{*} / \mathfrak{m}^{k} E_{*} \simeq E_{*} \otimes_{\mathbb{Z}} \mathbb{Z}_{p}, \end{align*}$$

where the limit on the left is taken in the category of $E_{*}E$ -comodules.

Note that $E_{*} \otimes _{\mathbb {Z}} \mathbb {Z}_{p} \simeq E_{*}(S^{0}_{p})$ , the homology of the p-complete sphere. Thus, the above result can be interpreted as detecting the conjectured copy of $L_{n-1}S^{0}_{p}$ inside $L_{n-1}S^{0}_{K}$ through E-homology.

At height 1, the Morava stabiliser group is particularly simple, and we are able to compute all of the derived limits.

Theorem F (15.12).

At height $n=1$ and any prime, we have

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^{s}(\mathbb{G}_{1}, E_{*}E) \simeq \begin{cases} E_{*} \otimes_{\mathbb{Z}} \mathbb{Z}_{p} & \mbox{when } s=0,\\ E_{*} \otimes_{\mathbb{Z}} \mathbb{Q}_{p}& \mbox{when } s=1,\\ 0 & \mbox{otherwise}. \end{cases} \end{align*}$$

Note that the above, in particular, completely recovers the height 1 case of the chromatic splitting conjecture, which states that $L_{0} L_{K(1)} S^{0} \simeq L_{0} S^{0}_{p} \oplus L_{0} S^{-1}_{p}$ . The latter can be equivalently obtained by explicitly computing $\pi _{*} L_{K}S^0$ , which, if we ignore torsion, contains exactly two $\mathbb {Z}_{p}$ summands, one for each sphere. However, the computation of homology gives more precise information, as the two copies of $\mathbb {Z}_{p}$ are isomorphic as abelian groups, but the comodules $E_{*} \otimes _{\mathbb {Z}} \mathbb {Z}_{p}$ and $E_{*} \otimes _{\mathbb {Z}} \mathbb {Q}_{p}$ are not.

Outline of document

We hope that the structure of the document becomes apparent from the choice of section titles. In brief, the first part of the paper, comprising Sections 2 through 6 deals with Morava K-theories, their Hopf algebroids, categories of comodules and their cohomology, through the perspective of Milnor modules. We pay special attention to the (in)dependence of our constructions on the choice of Morava K-theories, and revisit the relation to continuous cohomology.

The K-based Adams spectral sequence and the finite height Miller square are the topics of Part 2. We establish convergence properties in Section 7, then construct the finite height Miller square, and use it to relate it to the filtration by powers spectral sequence. In Section 10, the final section of this part, we illustrate our results by going through explicit computations at height 1.

The third part of the paper consists of Sections 11 to 15. Here, the focus lies on the derived category of $E_*E$ -comodules and the construction and study of the inverse limit spectral sequence. We then give our application to the algebraic chromatic splitting conjecture, based on the connection to the continuous cohomology of the Morava stabiliser group. Each of the two parts ends with some explicit computations at height 1, which we hope elucidate our methods and results.

Part 1. Morava K -theories and Milnor modules

In this part of the paper, we study Morava K-theories, which play the role of residue fields of Lubin–Tate spectra. We describe their Hopf algebroids, categories of comodules and cohomology.

2 Morava K-theories and their Hopf algebroids

Let $\kappa $ be a perfect field equipped with a choice of a height n formal group $\mathbf {G}_{0}$ . Associated to these data is the Lubin–Tate ring $E_{0}$ classifying deformations [Reference Lubin and TateLT66]. This is a complete local $W(\kappa )$ -algebra, such that there exists a noncanonical choice of regular generators inducing an isomorphism of rings $E_{0} \simeq W(\kappa )[\![ u_{1}, \ldots , u_{n-1}]\!]$ . We write $\mathfrak {m} = (p, u_{1} \ldots , u_{n-1})$ for the maximal ideal. The ring $E_{0}$ equipped with the universal deformation is Landweber exact and so can be lifted to a $2$ -periodic ring spectrum E with $E_{*} \simeq E_{0}[u^{\pm 1}]$ for some unit $u \in E_{2}$ , and the property that the formal group is the universal deformation of $\mathbf {G}_{0}$ . It is well-known that E admits a unique $\mathbf {E}_{\infty }$ -ring structure, functorial in the choice of $\kappa $ and the formal group (see [Reference Goerss and HopkinsGH05a]). More recently, it was proven by Lurie that E arises as a solution to a moduli problem involving formal groups over $\mathbf {E}_{\infty }$ -rings, see [Reference LurieLur18].

The canonical nature of the Lubin–Tate spectrum makes it a good starting point for the study of chromatic phenomena. Since $E_{0}$ is local, one would like to construct a spectrum which plays the role of the residue field of E. Following Hopkins and Lurie [Reference Hopkins and LurieHL17], we make the following definition.

Definition 2.1. An $\mathbf {E}_{1}$ -E-algebra K is a Morava K-theory if the unit map $E \rightarrow K$ induces an isomorphism $K_{*} \simeq E_{*} / \mathfrak {m}$ .

One can show that an algebra satisfying the above conditions always exists, for any Lubin–Tate spectrum E; in fact:

  1. (1) there are uncountably many Morava K-theories which are not equivalent as E-algebras,

  2. (2) none of which is preferred and

  3. (3) none of which can be promoted to an $\mathbf {E}_{2}$ -E-algebra

(see [Reference Hopkins and LurieHL17] for more information).

Warning 2.2. Large parts of the literature are written in terms of the $(2p^{n}-2)$ -periodic spectrum $K(n)$ with $\pi _{*}K(n) \simeq \mathbb {F}_{p}[v_{n}^{\pm 1}]$ ; this cannot be a made into a Morava K-theory according to the above definition, as it not $2$ -periodic. We do not use $K(n)$ in the current work, but in the interest of completeness, we collect some results about it in Section 3 below.

Throughout the rest of this section, the letter K denotes a choice of a Morava K-theory in the sense of Definition 2.1.

Remark 2.3. While two different Morava K-theories need not be equivalent as E-algebras, one can show that they are always equivalent as E-modules [Reference Hopkins and LurieHL17, Corollary 3.6.6]. In particular, they are always equivalent as spectra.

Observe that we have $K_{*} \simeq E_{*} / \mathfrak {m} E_{*}$ by definition, so $K_{*} \simeq \kappa [u^{\pm 1}]$ , which is a graded field. Note that the first isomorphism is completely canonical, while the second is not, as it depends on the choice of a unit $u \in K_{2}$ . In any case, it follows that the ring spectrum K is even periodic, and so complex-orientable. The reduction map $E^{0}(BS^{1}) \rightarrow K^{0}(BS^{1})$ induces a canonical isomorphism $\text {Spf}(K^{0}(BS^{1})) \simeq \mathbf {G}_{0}$ .

Remark 2.4. It is not strictly necessary to start relative to a chosen Lubin–Tate spectrum. Instead, one could say that an $\mathbf {E}_{1}$ -algebra K in spectra is a Morava K-theory if there exists an isomorphism $K_{*} \simeq \kappa [u^{\pm 1}]$ with $\kappa $ a perfect field and such that is of finite height. One can show that, in this case, K can be canonically lifted to an algebra over the corresponding Lubin–Tate ring spectrum. Thus, we lose no generality by working relative to E.

In this paper, we will be interested in the K-based Adams spectral sequence. By standard arguments, the $E_{2}$ -page of this spectral sequence has a description in terms of homological algebra of comodules over the Hopf algebroid $K_{*}K$ . Thus, we begin by giving a partial description of the latter.

Our strategy is to exploit the E-algebra structure on K to divide $K_{*}K$ into two parts, the first of which admits a convenient interpretation in terms of formal groups and the second of which is more mysterious but manageably small. We start with the latter, for which we need to work relative to E.

Notation 2.5. If $M, N$ are E-modules, we write

for their homology relative to E and

for their relative cohomology. Here, $F_{E}$ is the internal mapping E-module; that is, the right adjoint to the tensor product of E-modules.

By usual arguments involving flatness of $K_{*}^{E}K$ over $K_{*}$ , the map

$$\begin{align*}K \otimes_{E} K \rightarrow K \otimes_{E} K \otimes_{E} K \end{align*}$$

induces a $K_{*}$ -coalgebra structure on $K_{*}^{E}K$ . Note that this is an honest coalgebra structure; that is, the left and right units coincide, as they are necessarily maps of $E_{*}$ -algebras, of which $K_{*}$ is a quotient. Together with multiplication, this makes $K_{*}^{E}K$ into a Hopf algebra, which a priori need not be either commutative nor cocommutative.

Lemma 2.6. The coalgebra structure on $K_{*}^{E}K$ is dual to an exterior algebra on an n-dimensional vector space V in degree $-1$ . In particular, $K_{*}^{E}K$ is cocommutative.

Proof. Since the coefficients of K form a field, we have an isomorphism of algebras

$$\begin{align*}\operatorname{\mathrm{Hom}}_{K_{*}}(K_{*}^{E}K, K_{*}) \simeq [K, K]_{*}^{E}, \end{align*}$$

where on the right-hand side, we have maps of E-modules. One can show that the latter is always isomorphic to an exterior algebra over a vector space of the needed dimension (see [Reference Hopkins and LurieHL17, Proposition 6.5.1]).

Remark 2.7. Hopkins and Lurie show that $K_{*}^{E}K$ is actually isomorphic to an exterior algebra as a Hopf algebra, though there is, in general, no canonical such isomorphism [Reference Hopkins and LurieHL17, Proposition 5.2.4]. In particular, it is also always commutative.

Remark 2.8. As both sides are $K_{*}$ -vector spaces of dimension $2^{n}$ , the latter by Lemma 2.6, the Künneth spectral sequence

$$\begin{align*}\operatorname{\mathrm{Tor}}_{t, s}^{E_{*}}(K_{*}, K_{*}) \implies K_{s+t}^{E}K \end{align*}$$

collapses. Indeed, since $E_{0}$ is a regular ring of dimension n, the relevant $\operatorname {\mathrm {Tor}}$ -groups are canonically isomorphic to an exterior algebra on n generators.

The second, ‘understandable’ part of $K_{*}K$ is the image of the canonical map from $E_{*}E$ , which can be identified with $K_{*}E$ . The analogue of this Hopf algebroid for the minimal Morava K-theory of Section 3 is denoted in Ravenel’s book by $\Sigma (n)$ (see [Reference RavenelRav03, §6.2]). Notice that since $E_{*}E$ is flat over $E_{*}$ , we have canonical isomorphisms

$$\begin{align*}K_{*}E \simeq K_{*} \otimes_{E_{*}} E_{*}E \simeq E_{*} E / \mathfrak{m}, \end{align*}$$

which in turn have the following consequence.

Proposition 2.9. The category of $K_{*}E$ -comodules is independent of K; more precisely, for any two choices of Morava K-theories, possibly over different Lubin–Tate spectra, these categories of comodules are canonically equivalent as symmetric monoidal categories.

Proof. By a result of Hovey–Strickland, see [Reference Hovey and StricklandHS05a, Theorem C], the categories of $E_{*}E$ -comodules for varying Lubin–Tate spectra E are canonically equivalent as locally graded symmetric monoidal categories.

The category of $K_{*}E$ -comodules can be identified with $K_{*}$ -modules in the symmetric monoidal category $\operatorname {\mathrm {Comod}}_{E_*E}$ , and $K_{*} \simeq E_{*} / \mathfrak {m}$ itself is uniquely determined as the minimal quotient of $E_{*}$ as a comodule by [Reference Hovey and StricklandHS05a, Theorem D]. Thus, the equivalence of Hovey and Strickland induces one between categories of $K_{*}E$ -comodules.

In fact, we can give a direct algebro-geometric description of this category of comodules. By standard results about Landweber exact homology theories, we have

$$\begin{align*}E_{*}E \simeq E_{*} \otimes_{BP_{*}} BP_{*}BP \otimes_{BP_{*}} E_{*}, \end{align*}$$

and by again invoking flatness, we see that

$$\begin{align*}K_{*}E \simeq K_{*} \otimes_{BP_{*}} BP_{*}BP \otimes_{BP_{*}} E_{*}. \end{align*}$$

Since the ideal $I_{n}$ is invariant, we can instead write

$$\begin{align*}K_{*}E \simeq K_{*} \otimes_{BP_{*}} BP_{*}BP \otimes_{BP_{*}} K_{*}. \end{align*}$$

This is a familiar Hopf algebroid, commutative ring homomorphisms out of which classify pairs of homomorphisms $f_{1}, f_{2}: K_{*} \rightarrow A$ together with a strict isomorphism of the resulting formal groups $(f_{1})^{*} \mathbf {G}_{0} = (f_{2})^{*} \mathbf {G}_{0}$ . In other words, we have a pullback of algebraic stacks

where $\mathcal {M}_{fg}^{\omega =\mathrm {1}}$ is the moduli of formal groups with a trivialised Lie algebra. The maps from $\operatorname {\mathrm {Spec}}(K_{*})$ are faithfully flat surjections onto the height n point in this moduli stack, and we deduce that the groupoid $(\operatorname {\mathrm {Spec}}(K_{*}), \operatorname {\mathrm {Spec}}(K_{*}E))$ is its presentation.

Proposition 2.10. The category of even graded $K_{*}E$ -comodules is equivalent to the category of quasi-coherent sheaves over the moduli stack $\mathcal {M}_{fg}^{n}$ of formal groups of height exactly n.

Proof. By the discussion above, the category of ungraded $K_{*}E$ -comodules can be identified with the category of quasicoherent sheaves over the moduli stack $\mathcal {M}_{fg}^{n, \omega =1}$ of formal groups of height n with trivialised Lie algebra.

The even grading of $K_{*}E$ corresponds under this equivalence to the $\mathbf {G}_{m}$ -action on the chosen trivialisation of the Lie algebra, so that even graded comodules can be identified with the quasicoherent sheaves over the quotient stack

which is exactly the claim.

The above discussion identifies $K_{*}E$ with familiar objects from the theory of formal groups, which is why we referred to it above as the ‘understandable’ part of $K_{*}K$ . The following gives some control over how these two parts are related.

Lemma 2.11. Consider $K \otimes E$ as an E-module with the module structure inherited only from the right factor. Then, $K \otimes E$ is equivalent as an E-module to a direct sum of Ks.

Proof. We will show something stronger, namely, that the $E \otimes E$ -modules $K \otimes E$ and $E \otimes K$ are equivalent. Since the latter has the needed property, as it admits a structure of a K-module from its right factor, this will be enough. At the level of homotopy groups, the induced maps $E_{*}E \rightarrow E_{*}K$ and $E_{*}E \rightarrow K_{*}E$ are both quotients by $\mathfrak {m} E_{*}E = E_{*}E \mathfrak {m}$ , where the equality is the statement that $\mathfrak {m}$ is an invariant ideal. Since $\mathfrak {m}$ is generated by a regular sequence, the needed statement will follow from the following result: Let  be a commutative algebra in spectra, and let $B \in \operatorname {\mathrm {Alg}}(\operatorname {\mathrm {Mod}}_{A})$ be an algebra whose unit map induces an isomorphism, $B_{*} \simeq A_{*}/I$ , where I is an ideal generated by a regular sequence $x_{1}, \ldots x_{n}$ . Then we have an equivalence of A-modules

$$\begin{align*}B \simeq \bigotimes_{A} \mathrm{cofib}(x_{i} \colon A \rightarrow A). \end{align*}$$

In particular, as an A-module B is determined up to equivalence by I.

To see this, note that since $1 \in B_{*}$ is $x_{i}$ -torsion, the unit factors through a map $\mathrm {cofib}(x_{i}) \rightarrow A$ . Then the composite

$$\begin{align*}\bigotimes_{A} \mathrm{cofib}(x_{i}) \rightarrow \bigotimes_{A} B \rightarrow B, \end{align*}$$

where the second map is the algebra multiplication, is an isomorphism on homotopy groups and thus an equivalence.

Corollary 2.12. Consider $K \otimes E$ as an E-module with the module structure inherited only from the right. Then, the Künneth spectral sequence

$$\begin{align*}\operatorname{\mathrm{Tor}}^{E_{*}}(K_{*}E, K_{*}) \implies \pi_{*}((K \otimes E) \otimes_{E} K) \simeq K_{*}K \end{align*}$$

in E-modules collapses.

Proof. This is immediate from Lemma 2.11 and Remark 2.8, as the Künneth spectral sequence depends only on the E-module structure.

Proposition 2.13. The map $K_{*}E \rightarrow K_{*}K$ is injective, central and presents the target as a free $K_{*}E$ -module of rank $2^{n}$ .

Proof. To see that the map is central, notice that $K \otimes K$ is canonically an $E \otimes E$ -algebra. It follows that the map $E_{*}E \rightarrow K_{*}K$ is central, and thus so must be its image $K_{*}E \simeq K_{*} \otimes _{E_{*}} E_{*}E$ .

As a consequence of Corollary 2.12, the Künneth spectral sequence

$$\begin{align*}K_{*}E \otimes \operatorname{\mathrm{Tor}}^{E_{*}}(K_{*}, K_{*}) \simeq \operatorname{\mathrm{Tor}}^{E_{*}}(K_{*}E, K_{*}) \implies K_{*}K \end{align*}$$

in E-modules collapses. Since the $\operatorname {\mathrm {Tor}}$ -groups on the left form a $K_{*}$ -vector space of dimension $2^{n}$ , it follows from the above collapse that $K_{*}K$ has a finite filtration as a $K_{*}E$ -module, such that the associated graded is free of rank $2^{n}$ . Thus, $K_{*}K$ itself must be free of this rank as well.

Proposition 2.14. Passing to homotopy groups in the diagram

induces an isomorphism

$$\begin{align*}K _{*}K \otimes_{K_{*}E} K_{*} \simeq K_{*}^{E}K. \end{align*}$$

Proof. Both of the Künneth spectral sequences for $K \otimes K \simeq (K \otimes E) \otimes _{E} K$ and $K \otimes _{E} K$ collapse, as a consequence of Corollary 2.12 and Remark 2.8. Thus, the map $K_{*}K \rightarrow K_{*}^{E}K$ is surjective after passing to associated graded, and so surjective by an inductive argument. The conclusion follows by observing that $K_{*} \otimes _{K_{*}E} K _{*}K \rightarrow K_{*}^{E}K$ is a surjective map of $K_{*}$ -vector spaces of the same dimension.

We are now ready to assemble the above information. By standard arguments, the pair $(K_{*}, K_{*}K)$ acquires the structure of a Hopf algebroid. More precisely, the two maps $K \rightarrow K \otimes K$ induce left and right units, both of which are central as a consequence of Proposition 2.13, as they factor through $K_{*}E$ . These make $K_{*}K$ into a $K_{*}$ -bimodule, and similarly, we get a suitable comultiplication and antipode.

Note that it is common in algebraic topology literature to assume in the definition of a Hopf algebroid that multiplication is commutative. However, this is not strictly necessary; in our case, as the units are central, $K_{*}K$ is a Hopf algebroid in the more general sense of Maltsiniotis [Reference MaltsiniotisMal92]. The category of comodules can be defined in the usual way, and it will be monoidal with the tensor product lifting that of $K_{*}$ -modules. It need not, in general, be symmetric monoidal.

Remark 2.15. We believe it is plausible that $K_{*}K$ is, in fact, always commutative; it is a finite algebra over the commutative algebra $K_{*}E$ with the relative tensor product $K_{*} \otimes _{K_{*}E} K_{*}K \simeq K_{*}^{E} K$ also commutative, as a consequence of Remark 2.7. We were, however, not able to resolve this question. Note that $K_{*}K$ is automatically commutative if we choose a homotopy commutative Morava K-theory, as can always be done when $p> 2$ [Reference Hopkins and LurieHL17, Proposition 3.5.2].

Theorem 2.16. The natural maps

(2.17) $$ \begin{align} (K_{*}, K_{*}E) \rightarrow (K_{*}, K_{*}K) \rightarrow (K_{*}, K_{*}^{E}K) \end{align} $$

form an extension of Hopf algebroids in the sense of Ravenel.

Proof. We first recall the relevant notation and definitions from [Reference RavenelRav03, Section A.1]. If $(A, \Gamma )$ is a Hopf algebroid, M is a right $\Gamma $ -comodule and N is a left $\Gamma $ -comodule, then the cotensor product is defined as the equalizer

between the two possible comultiplications. Two particularly important cases are

$$\begin{align*}N \square_{\Gamma} A \simeq \operatorname{\mathrm{Ext}}^{0}_{\operatorname{\mathrm{Comod}}_{\Gamma}^{R}}(A, N), \end{align*}$$

the coinvariants in the category of right comodules and

$$\begin{align*}N \square_{\Gamma} A \simeq \operatorname{\mathrm{Ext}}^{0}_{\operatorname{\mathrm{Comod}}_{\Gamma}^{L}}(A, N), \end{align*}$$

the coinvariants in the category of left comodules. Since $K_{*}K \rightarrow K_{*}^{E}K$ is surjective, consulting Ravenel’s definitions of a normal map of Hopf algebroids and of an extension [Reference RavenelRav03, A.1.1.10, A.1.1.15], we see that in our case, we have to verify that

  1. (1) $K_{*} \square _{K_{*}^{E}K} K_{*}K = K_{*}K \square _{K_{*}^{E}K} K_{*}$ ,

  2. (2) $K_{*} \square _{K_{*}^{E}K} K_{*} = K_{*}$ ,

  3. (3) $K_{*} \square _{K_{*}^{E}K} K_{*}K \square _{K_{*}^{E}K} K_{*} = K_{*}E$ .

We begin with the first part. If we write

$$\begin{align*}K_{*}K \simeq \pi_{*}(K \otimes K) \simeq \pi_{*}(K \otimes_{E} E \otimes K) \simeq K_{*}^{E}(E \otimes K), \end{align*}$$

then the left $K_{*}^{E}K$ -comodule structure on $K_{*}K$ given by the quotient map $K_{*}K \rightarrow K_{*}^{E}K$ corresponds to the standard comodule structure on the relative homology $K_{*}^{E}(E \otimes K)$ relative to E. This comodule structure map is determined by the structure of $E \otimes K$ as a left E-module with module structure coming only from the left factor. By Lemma 2.11, $E \otimes K$ is equivalent as an E-module to a direct sum of K, and so admits a compatible structure of a K-module. Choosing such a K-module structure determines an isomorphism

$$\begin{align*}K_{*}^{E}(E \otimes K) \simeq K_{*}^{E}K \otimes_{K_{*}} \pi_{*}(E \otimes K) \simeq K_{*}^{E}K \otimes_{K_{*}} E_{*}K \end{align*}$$

of left comodules, so that

$$\begin{align*}K_{*} \square_{K_{*}^{E}K} K_{*}K \simeq K_{*} \square_{K_{*}^{E}K} K_{*}^{E}(E \otimes K) \simeq K_{*} \square_{K_{*}^{E}K} (K_{*}^{E}K \otimes E_{*}K) \simeq E_{*}K \end{align*}$$

as needed.

Using symmetry, Lemma 2.11 similarly shows that

$$\begin{align*}K_{*}K \simeq K_{*}E \otimes_{K_{*}} K_{*}^{E}K \end{align*}$$

as right $K_{*}^{E}K$ -comodules, so that

$$\begin{align*}K_{*}K \square_{K_{*}^{E}K} K_{*} \simeq K_{*}E. \end{align*}$$

As $K_{*}E$ and $E_{*}K$ coincide as subobjects of $K_{*}K$ , this shows part $(1)$ and part $(3)$ . Part $(2)$ is an observation that $K_{*}^{E}K$ is a Hopf algebra rather than a Hopf algebroid.

3 Digression: Minimal Morava K-theory

Large parts of the literature on Morava K-theories are written in terms of the minimal Morava K-theory spectrum $K(n)$ , the unique up to equivalence $BP$ -module with $K(n)_{*} \simeq \mathbb {F}_{p}[v_{n}^{\pm 1}]$ . Note that it is not a Morava K-theory in the sense of Definition 2.1 as it is not $2$ -periodic, but as a consequence of nilpotence theorem, any Morava K-theory is equivalent as a spectrum to a direct sum of $K(n)$ [Reference Hopkins and SmithHS98, Lemma 1.8].

Our focus on $2$ -periodic Morava K-theories stems from our preference for Lubin–Tate spectra as they admit canonical $\mathbf {E}_{\infty }$ -structures, unlike the Brown–Peterson spectrum. In this short section, we collect some results about $K(n)$ to highlight similarities and differences with the E-algebra version. We do this for completeness; these results will not be used elsewhere in the current work.

It is a result of Robinson that $K(n)$ can be made into an $\mathbf {E}_{1}$ -ring spectrum, but there is no canonical way to do so [Reference RobinsonRob89]. A surprising result of Angeltveit shows that all choices of $\mathbf {E}_{1}$ -multiplications yield equivalent $\mathbf {E}_{1}$ -algebras in spectra [Reference AngeltveitAng11].

One can also ask about less structured multiplication. By a theorem of Würgler [Reference WürglerWür91], in the homotopy category of spectra, the spectrum $K(n)$ admits,

  1. (1) if $p> 2$ , a unique product $K(n) \otimes K(n) \rightarrow K(n)$ ;

  2. (2) if $p = 2$ , exactly two products $K(n) \otimes K(n) \rightarrow K(n)$ differing by the symmetry on $K(n) \otimes K(n)$ ,

which make it into an associative $BP$ -algebra in a way compatible with its $BP$ -module structure [Reference WürglerWür91, Theorem 1.5].

The ring of cooperations of $K(n)$ has been computed completely [Reference WürglerWür91, Theorem 2.4]. The map $K(n)_{*}BP \rightarrow K(n)_{*}K(n)$ is injective, and we have an isomorphism

$$\begin{align*}K(n)_{*}BP \simeq K(n)_{*}[t_{i}] / (v_{n} t_{i}^{p^{n}} - v_{n}^{p^{i}} t_{i}), \end{align*}$$

where $|t_{i}| = 2p^{i}-2$ for $i \geq 1$ . At odd primes, this extends to an isomorphism

$$\begin{align*}K(n)_{*}K(n) \simeq K(n)_{*}BP \otimes _{K(n)_{*}} \Lambda_{K(n)_{*}}(\tau_{0}, \ldots, \tau_{n-1}), \end{align*}$$

where the latter factor is an exterior algebra on $|\tau _{i}| = 2p^{i}-1$ . When $p = 2$ , we instead have that

$$\begin{align*}K(n)_{*}K(n) \simeq K(n)_{*}BP \otimes _{K(n)_{*}} K(n)_{*}[\tau_{0}, \ldots, \tau_{n-1}] / (\tau_{i}^{2} = t_{i+1}). \end{align*}$$

This is analogous to the variation in the dual Steenrod algebra depending on whether p is even or odd. Note that the latter computation implies that $K(n)_{*}K(n)$ is commutative also at $p=2$ , despite $K(n)$ not being homotopy commutative. The corresponding question in the $2$ -periodic case is open (see Remark 2.15).

4 Milnor modules

As we have seen in the previous section, there are many different Morava K-theory spectra, which makes any discussion of this subject dependent on these choices. However, as in the case of Proposition 2.9, one can show that many cohomological invariants are canonical and do not depend on any choices. In this section, we make this canonical nature transparent by introducing an absolute variant of Hopkins and Lurie’s categories of Milnor modules (see [Reference Hopkins and LurieHL17]).

Before we work in the absolute case, let us first describe the case relative to a fixed Lubin–Tate spectrum E. Note that by the uniqueness part of the Goerss–Hopkins–Miller theorem, see [Reference Goerss and HopkinsGH, Corollary 7.6] or [Reference Pstragowski and VanKoughnettPV22, Theorem 7.7], this is the same as choosing a perfect field equipped with a finite height formal group.

Definition 4.1. We say that an E-module is molecular if it is equivalent to a finite sum of shifts of Morava K-theories of E, and denote the full subcategory of E-modules on the molecular objects by $\operatorname {\mathrm {Mod}}^{mol}_{E}$ .

Remark 4.2. Note that since any two Morava K-theories of E are equivalent as E-modules, the notion of being molecular does not depend on any choices.

Definition 4.3. The category of E-based Milnor modules is the category

of additive presheaves of abelian groups on molecular E-modules.

By construction, the category of Milnor modules is a compactly generated Grothendieck abelian category. Since molecular E-modules are stable under the E-tensor product, it acquires a nonunital symmetric monoidal structure via left Kan extension. One can show this extends uniquely to a unital symmetric monoidal structure [Reference Hopkins and LurieHL17, Propositions 4.4.1 and 4.4.10].

The main property of Milnor modules is that it canonically captures cohomology of any Morava K-theory relative to E, in the following sense.

Proposition 4.4. Let K be a Morava K-theory of E. Then, the left Kan extension of the functor

$$\begin{align*}K_{*}^{E}(-): \operatorname{\mathrm{Mod}}_{E}^{mol} \rightarrow \operatorname{\mathrm{Comod}}_{K_{*}^{E}K} \end{align*}$$

which associates to any molecular E-module its relative K-homology induces a monoidal equivalence

$$\begin{align*}\operatorname{\mathrm{Mil}}_{E} \simeq \operatorname{\mathrm{Comod}}_{K_{*}^{E}K} \end{align*}$$

between Milnor modules and $K_{*}^{E}K$ -comodules.

Proof. This is [Reference Hopkins and LurieHL17, Corollary 6.4.13], where we replaced the category of modules over $K^{*}_{E}K$ with comodules over its linear dual.

Corollary 4.5. As a monoidal category, $\operatorname {\mathrm {Comod}}_{K_{*}^{E}K}$ does not depend on the choice of K but only on its corresponding formal group.

Remark 4.6. Note that in the context of Corollary 4.5, the situation is somewhat better than just saying that the categories $\operatorname {\mathrm {Comod}}_{K_{*}^{E}K}$ for fixed E and varying K are all equivalent to each other. In fact, they are all canonically equivalent to a single category which doesn’t depend on any choices, namely, the category of Milnor modules of E.

Remark 4.7. The category $\operatorname {\mathrm {Mil}}_{E}$ is not only canonical but, in a certain, sense gives the right answer even if $K_{*}^{E}K$ -comodules do not. As an example, the restricted Yoneda embedding

$$\begin{align*}y\colon \operatorname{\mathrm{Mod}}_{E} \rightarrow \operatorname{\mathrm{Mil}}_{E}, \end{align*}$$

which can be thought of as a way of taking relative K-homology without choosing K, is always a symmetric monoidal functor [Reference Hopkins and LurieHL17, Variant 4.4.11].

On the other hand, even if K is not homotopy commutative, $K_{*}^{E}K$ is both commutative and cocommutative so that the category $\operatorname {\mathrm {Comod}}_{K_{*}^{E}K}$ acquires a symmetric monoidal structure from $K_{*}$ -vector spaces. However, in this case, the relative K-homology functor

$$\begin{align*}K_{*}^{E}(-): \operatorname{\mathrm{Mod}}_{E} \rightarrow \operatorname{\mathrm{Comod}}_{K_{*}^{E}K} \end{align*}$$

need not be symmetric monoidal.

If K is homotopy commutative, then the above homology theory is canonically symmetric monoidal so that we have a symmetric monoidal equivalence $\operatorname {\mathrm {Comod}}_{K_{*}^{E}K} \simeq \operatorname {\mathrm {Mil}}_{E}$ . Informally, any algebraic structure which one can put on $\operatorname {\mathrm {Comod}}_{K_{*}^{E}K}$ in a way compatible with the homology functor from E-modules must already be present in the category of Milnor modules.

Let us now describe the global analogue of this situation, which describes the Adams spectral sequence in spectra rather than E-modules; alternatively, which describes comodules over $K_{*}K$ rather than the relative variant $K_{*}^{E}K$ .

In Miller’s approach to the Adams spectral sequence, the latter is determined by the class of maps, which are K-split; that is, which are split epimorphisms after applying $K \otimes -$ . This only depends on the structure of K as a spectrum and does not require any coherent multiplication.

As a consequence of the nilpotence theorem, all Morava K-theories at a fixed prime and height are, as spectra, direct sums of the minimal Morava K-theory spectrum of Section 3. It follows that they all determine the same class of epimorphisms, and hence isomorphic Adams spectral sequences. In fact, the class of epimorphisms is enough to describe canonically the abelian category whose $\operatorname {\mathrm {Ext}}$ -groups form the $E_{2}$ -page. To do so, we consider sheaves with respect to a certain topology, as in the construction of synthetic spectra [Reference PstragowskiPst22].

Definition 4.8. The $K_{*}$ -epimorphism topology on the $\infty $ -category of finite spectra is the Grothendieck pretopology in which a family $\{ X \rightarrow Y \}$ is covering if and only if it consists of a single map, such that $K_{*} X \rightarrow K_{*} Y$ is surjective.

Remark 4.9. A reader familiar with [Reference PstragowskiPst22] might recall that in the construction of synthetic spectra, one works with the site of those finite spectra X, such that $K_{*}X$ is projective as a $K_{*}$ -module [Reference PstragowskiPst22, Definition 3.12]. Since Morava K-theories are fields, this yields the class of all finite spectra, as above.

Definition 4.10. The category of absolute Milnor modules is the category

of additive sheaves of abelian groups on finite spectra with respect to the $K_{*}$ -epimorphism topology.

The category of absolute Milnor modules is a compactly generated Grothendieck abelian category with a symmetric monoidal structure induced by that of the tensor product of finite spectra.

Remark 4.11. A reader familiar with synthetic spectra might immediately recognise that the category of Milnor modules can be canonically identified as , the heart of the stable $\infty $ -category of K-based synthetic spectra of [Reference PstragowskiPst22].

The following is the absolute analogue of Proposition 4.4.

Proposition 4.12. If K is a Morava K-theory, then the left Kan extension of the functor

$$\begin{align*}K_{*}: \operatorname{\mathrm{Sp}}^{fin} \rightarrow \operatorname{\mathrm{Comod}}_{K_{*}K} \end{align*}$$

induces a monoidal equivalence

$$\begin{align*}\operatorname{\mathrm{Mil}}_{abs} \simeq \operatorname{\mathrm{Comod}}_{K_{*}K} \end{align*}$$

between absolute Milnor modules and $K_{*}K$ -comodules.

Proof. This is an instance of [Reference PstragowskiPst22, Remark 3.26].

As a consequence, we deduce the following result proven earlier by Hovey and Strickland using slightly different methods [Reference Hovey and StricklandHS05a, Section 8].

Corollary 4.13. The monoidal category $\operatorname {\mathrm {Comod}}_{K_{*}K}$ of $K_{*}K$ -comodules does not depend on the choice of Morava K-theory but only on the prime and height.

Remark 4.14. By the same argument as in the relative case of Remark 4.7, if K is homotopy commutative, then we have a canonical symmetric monoidal equivalence $\operatorname {\mathrm {Mil}}_{abs} \simeq \operatorname {\mathrm {Comod}}_{K_{*}K}$ .

Remark 4.15 (Homological residue fields).

In the terminology of Balmer, the category of Milnor modules is the homological residue field of the tensor-triangulated category of finite spectra at the prime ideal of spectra of type at least n (see [Reference BalmerBal20], [Reference Balmer and CameronBC21]).

Remark 4.16 (Milnor modules as sheaves).

The reader can observe that there is a certain asymmetry in our definitions of Milnor modules and absolute Milnor modules; namely, in the former case, we use as our indexing category only molecular E-modules, and in the latter case, we use all finite spectra. Moreover, in the latter case, we use sheaves, while in the former, presheaves are already enough.

In fact, this difference is but a trick of light, as there is an alternative description of Milnor modules which is more in line with the absolute case. Namely, one can show that $\operatorname {\mathrm {Mil}}_E$ is equivalent to the category of sheaves on the $\infty $ -category $\operatorname {\mathrm {Mod}}^{perf}_{E}$ of perfect E-modules with respect to the $K_{*}^{E}(-)$ -epimorphism topology. Under this topology, the functor

becomes a morphism of sites, so that left Kan extension yields a cocontinuous, symmetric monoidal functor

$$\begin{align*}\operatorname{\mathrm{Mil}}_{abs} \rightarrow \operatorname{\mathrm{Mil}}_{E}. \end{align*}$$

In this sense, absolute Milnor modules determine a relative Milnor module, for any choice of E, justifying the terminology.

Under the equivalences of Propositions 4.4 and 4.12, the above left Kan extension corresponds to the forgetful functor

$$\begin{align*}\operatorname{\mathrm{Comod}}_{K_{*}K} \rightarrow \operatorname{\mathrm{Comod}}_{K_{*}^{E}K}. \end{align*}$$

The image of the monoidal unit under the corresponding right adjoint can be identified with the Hopf algebroid $K_{*}E$ studied previously. As the Adams spectral sequence based on $K_{*}E$ in the appropriate derived $\infty $ -categories can be identified with the Cartan–Eilenberg spectral sequence associated to this extension of Hopf algebroids [Reference BelmontBel20, Theorem 1.1], we deduce that the Cartan–Eilenberg spectral sequence itself can be constructed using only the categories of Milnor modules, so it only depends on E.

5 Cohomology

In this section, we establish finiteness properties of the cohomology of $K_{*}K$ -comodules using the Cartan–Eilenberg spectral sequence.

We have seen in Theorem 2.16 that we have an extension of Hopf algebroids

$$\begin{align*}(K_{*}, K_{*}E) \rightarrow (K_{*}, K_{*}K) \rightarrow (K_{*}, K_{*}^{E}K) \end{align*}$$

which induces a Cartan–Eilenberg spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Ext}}^{s}_{K_{*}E}(K_{*}, \operatorname{\mathrm{Ext}}^{s^{\prime}}_{K_{*}^{E}K}(K_{*}, K_{*})) \implies \operatorname{\mathrm{Ext}}^{s + s^{\prime}}_{K_{*}K}(K_{*}, K_{*}) \end{align*}$$

(see [Reference RavenelRav03, A.1.3.14]). This can be thought of as approximating the cohomology of $K_{*}K$ using simpler pieces, namely, the cohomology of $K_{*}E$ and $K_{*}^{E}K$ . To make the best use of this, we need to begin by understanding the latter two. We have seen in Section 2 that the Hopf algebroid $(K_{*}, K_{*}E)$ is an even graded presentation of the moduli of formal groups of height exactly n (see Proposition 2.10). To identify its cohomology, it is convenient to choose a particularly small presentation of the latter moduli stack, which is what we will do.

Notation 5.1. We follow the conventions of [Reference Goerss, Henn, Mahowald and RezkGHMR05, Section 2]. Let $\mathbf {G}_{0}$ be the Honda formal group law over $\mathbb {F}_{q}$ , where $q = p^{n}$ , and let $E_{n}$ be the associated Lubin–Tate spectrum and $K_{n}$ a Morava K-theory associated to $E_{n}$ . Note that we have a noncanonical isomorphism

$$\begin{align*}\pi_{0} E_{n} \simeq W(\mathbb{F}_{q})[[u_{1}, \ldots, u_{n-1}]], \end{align*}$$

and a canonical isomorphism

$$\begin{align*}\pi_{*} E_{n} \simeq (\pi_{0} E_{n})[u^{\pm 1}] \end{align*}$$

with $|u| = -1$ . We write $\mathbb {G}_{n} \simeq \mathbb {S}_{n} \rtimes \text {Gal}(\mathbb {F}_{q} / \mathbb {F}_{p})$ for the extended Morava stabiliser group, the automorphism group of the pair $(\operatorname {\mathrm {Spec}}(\mathbb {F}_{q}), \mathbf {G}_{0})$ ; see [Reference HennHen17, Section 4.1] for an explicit description of this group. By the functoriality of the Goerss–Hopkins–Miller theorem [Reference Goerss and HopkinsGH05b], the canonical action of $\mathbb {G}_{n}$ on $(\operatorname {\mathrm {Spec}}(\mathbb {F}_{q}), \mathbf {G}_{0})$ induces a left action on the Lubin–Tate spectrum  $E_{n}$ .

Lemma 5.2. The association $\mathbb {G}_{n} \times (K_{n})_{*}E_{n} \rightarrow (K_{n})_{*}$ sending an element $g \in \mathbb {G}_{n}$ and a homotopy class $S^{k} \rightarrow K_{n} \otimes E_{n}$ to the homotopy class of the composite

induces an isomorphism $\operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{n}, (K_{n})_{*}) \simeq (K_{n})_{*}E_{n}$ of algebras between the $K_{n}$ -homology of $E_{n}$ and continuous functions on the Morava stabiliser group.

Proof. This is a result of Strickland, reduced modulo $\mathfrak {m}$ [Reference StricklandStr00, Theorem 12].

One can check that the above isomorphism is compatible with the Hopf algebroid structure, which is induced from the group structure on $\mathbb {G}_{n}$ and its action on $(K_{n})_{*} \simeq \mathbb {F}_{q}[u^{\pm 1}]$ , which yields the following.

Corollary 5.3. For any Morava K-theory K, there is a canonical equivalence of categories between $K_{*}E$ -comodules and graded $\mathbb {F}_{q}[u^{\pm 1}]$ -vector spaces equipped with a continuous action of the extended Morava stabiliser group $\mathbb {G}_{n}$ .

Proof. We have proven previously in Proposition 2.9 that the category of $K_{*}E$ -comodules is independent of the choice of K. For the particular choice of $K = K_{n}$ as above, this equivalence of categories is induced by Lemma 5.2.

Remark 5.4. In terms of the equivalence $\operatorname {\mathrm {Comod}}_{K_{*}E}^{ev} \simeq \operatorname {\mathrm {QCoh}}(\mathcal {M}_{fg}^{n})$ of Proposition 2.10, Corollary 5.3 is a consequence of the fact that the map $\mathbb {F}_{q} \rightarrow \mathcal {M}_{fg}^{n}$ classifying the Honda formal group law is a Galois covering with automorphism group $\mathbb {G}_{n}$ ; we refer to [Reference GoerssGoe08] for further details.

Corollary 5.5. For any Morava K-theory, there is a canonical isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}_{K_{*}E}^{s, t}(K_{*}, K_{*}) \simeq \mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, \mathbb{F}_{q}[u^{\pm 1}]) \end{align*}$$

between the cohomology of the Hopf algebroid $(K_{*}, K_{*}E)$ and the continuous cohomology of the Morava stabiliser group.

The group $\mathbb {G}_{n} \simeq \mathbb {S}_{n} \rtimes \text {Gal}(\mathbb {F}_{q} / \mathbb {F}_{p})$ is a semidirect product of the automorphism group $\mathbb {S}_{n}$ of $\mathbf {G}_{0}$ and the Galois group. The former is a p-adic Lie group, in fact, a group of units in the integers of the central division algebra over $\mathbb {Q}_{p}$ of Hasse invariant $\frac {1}{n}$ , which gives its excellent cohomological properties.

The action of the Morava stabiliser group on $\mathbb {F}_{q}[u^{\pm 1}]$ is easy to describe. The Galois group acts by its standard action on $\mathbb {F}_{q}$ . The action of $\mathbb {S}_{n}$ factors through the leading coefficient homomorphism $\rho \colon \mathbb {S}_{n} \rightarrow \mathbb {F}_{q}^{\times }$ and is determined by the formula $s \cdot u = p(s)u$ for $s \in \mathbb {S}_{n}$ . The kernel of $\rho $ is the strict Morava stabiliser group $S_{n}$ ; it is a pro-p-group acting trivially. Morava [Reference MoravaMor85] essentially proved:

Theorem 5.6 (Morava).

We have isomorphisms of continuous cohomology groups

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^*(\mathbb{G}_n,\mathbb{F}_{q}[u^{\pm 1}]) \simeq \mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{S}_{n}, \mathbb{F}_{q}[u^{\pm 1}])^{\mathrm{Gal}} \simeq \mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(S_{n}, \mathbb{F}_{q}[u^{\pm 1}])^{\mathbb{F}_{q}^{\times} \rtimes \mathrm{Gal}}. \end{align*}$$

Moreover, these groups are finite in each bidegree. If $(p-1) \nmid n$ , this is a Poincaré duality algebra over $\mathrm {H}_{\operatorname {\mathrm {cts}}}^{0} \simeq \mathbb {F}_{p}[v_{n}^{\pm 1}]$ of dimension $n^{2}$ , where , in particular, their total dimension is finite.

Proof. These isomorphisms are induced by the collapse of the respective Lyndon–Hochschild–Serre spectral sequences, as neither $\mathrm {Gal}$ nor $\mathbb {F}_{q}^{\times }$ have any higher cohomology with these coefficients, the first one by Galois theory and the second one as it is of order coprime to p.

The finiteness statements are due to Lazard, as $S_{n}$ is a p-adic analytic Lie group of dimension $n^{2}$ and so has a finite index subgroup whose cohomology is isomorphic to an exterior algebra [Reference Symonds and WeigelSW00, Theorem 5.1.5] of dimension $n^{2}$ . If $(p-1) \nmid n$ , then $S_{n}$ has no p-torsion, see [Reference HennHen98, Theorem 3.2.1], and so it has the same cohomological dimension as all of its finite index subgroups [Reference SerreSer65].

Corollary 5.7. For any finite-dimensional $K_{*}E$ -comodules $M, N$ , the groups $\operatorname {\mathrm {Ext}}^{t, s}_{K_{*}E}(M, N)$ are finite in each bidegree. If $(p-1) \nmid n$ , then they vanish for $s> n^{2}$ .

Proof. We first claim that any finite-dimensional $K_{*}E$ -comodule M has an invariant element; that is, there exists a nonzero map $K_{*} \rightarrow M$ of comodules (possibly of nonzero internal degree). Observe that M can be considered as an $E_{*}E$ -comodule using restriction along the maps $E_{*}E \rightarrow K_{*}E$ and $E_{*} \rightarrow K_{*}$ . As M is finitely generated over $E_{*}$ , it admits a nonzero map $E_{*} \rightarrow M$ of comodules by a result of Hovey and Strickland [Reference Hovey and StricklandHS05a, Theorem D]. As the target is $\mathfrak {m}$ -torsion, the map factors through a map $K_{*} \rightarrow M$ of $K_{*}E$ -comodules, which is what we were looking for.

We deduce that any finite-dimensional comodule M can be obtained as an iterated extension of shifts of $K_{*}$ . Indeed, this is clear if M is zero-dimensional. If $\dim _{K_{*}}(M)> 0$ , then by the above, we can find a nonzero map of comodules $K_{*} \rightarrow M$ , which is then necessarily injective. Then the cokernel is of lower dimension, and hence can be obtained as an iterated extension by induction.

Finally, observe that the finiteness of $\operatorname {\mathrm {Ext}}$ -groups holds when $M = N = K_{*}$ as a combination of Corollary 5.5 and Theorem 5.6. The general case is proven by presenting $M, N$ as iterated extensions as in the previous paragraph and using the corresponding long exact sequences of $\operatorname {\mathrm {Ext}}$ -groups.

To get hold of the Cartan–Eilenberg spectral sequence, we also need to have some control over the cohomology of $K_{*}^{E}K$ . By a result of Hopkins and Lurie, see Remark 2.7, the latter is isomorphic to an exterior algebra as a Hopf algebra, and so its cohomology is necessarily a polynomial ring. In fact, the same authors identify the generators of this polynomial ring, as we now recall.

Suppose that $x \in \mathfrak {m}$ is an element of the maximal ideal. We then have a cofibre sequence

$$\begin{align*}E \rightarrow E/x \rightarrow \Sigma E \end{align*}$$

of E-modules which induces a short exact sequence

$$\begin{align*}0 \rightarrow K_{*} \rightarrow K_{*}^{E}(E/x) \rightarrow K_{*}[1] \rightarrow 0 \end{align*}$$

of $K_{*}^{E}K$ -comodules. Let us denote by $\psi (x)$ the corresponding element of $\operatorname {\mathrm {Ext}}^{1, -1}_{K_{*}^{E}K}(K_{*}, K_{*})$ .

Proposition 5.8. The association $x \mapsto \psi (x)$ induces a map

$$\begin{align*}\mathfrak{m} / \mathfrak{m}^{2} \rightarrow \operatorname{\mathrm{Ext}}_{K_{*}^{E}K}^{1, -1}(K_{*}, K_{*}) \end{align*}$$

which extends to an isomorphism of bigraded rings

$$\begin{align*}K_{*} \otimes_{\kappa} \operatorname{\mathrm{Sym}}_{\kappa}^{*} (\mathfrak{m} / \mathfrak{m}^{2}) \simeq \operatorname{\mathrm{Ext}}_{K_{*}^{E}K}(K_{*}, K_{*}). \end{align*}$$

Proof. As we show in Proposition 4.4, the category of $K_{*}^{E}K$ -comodules can be identified, as a monoidal category, with the category of Milnor modules associated to E. It follows that we have

$$\begin{align*}\operatorname{\mathrm{Ext}}^{*}_{K_{*}^{E}K}(K_{*}, K_{*}) \simeq \operatorname{\mathrm{Ext}}^{*}_{\operatorname{\mathrm{Mil}}_{E}}(y(E), y(E)), \end{align*}$$

the cohomology in Milnor modules, where $y(E)$ is the Milnor module associated to E. For the right-hand side, the needed isomorphism is proven in [Reference Hopkins and LurieHL17, Proposition 7.2.7].

Remark 5.9. If we again let $K_{n}$ be any Morava K-theory associated to the Honda formal group over $\mathbb {F}_{q}$ , it follows that the Cartan–Eilenberg spectral sequence for cohomology of the unit has signature

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^{s_{0}}(\mathbb{G}_{n}, \mathbb{F}_{q}[u^{\pm 1}] \otimes_{\mathbb{F}_{q}} \operatorname{\mathrm{Sym}}^{s_{1}}_{\mathbb{F}_{q}}(\mathfrak{m} / \mathfrak{m}^{2})) \implies \operatorname{\mathrm{Ext}}^{s_{0} + s_{1}}_{K_{*}K}(K_{*}, K_{*}). \end{align*}$$

To determine the action on the symmetric algebra, it is convenient to work in the context of Milnor modules, as in the proof of Proposition 5.8. The category of Milnor modules $\operatorname {\mathrm {Mil}}_{E}$ is by construction functorial in automorphisms of E, and it is clear that the association $x \mapsto \psi (x)$ is natural with respect to the action of the Morava stabiliser group. It follows that the action of $\mathbb {G}_{n}$ on this symmetric algebra is the one induced by its action on the cotangent space $\mathfrak {m} / \mathfrak {m}^{2}$ of the Lubin–Tate ring.

Using the Cartan–Eilenberg spectral sequence, we can prove the following finiteness statement.

Theorem 5.10. Let $M, N$ be finite-dimensional $K_{*}K$ -comodules. Then, the group $\operatorname {\mathrm {Ext}}^{s, t}_{K_{*}K}(M, N)$ is finite in each bidegree.

Proof. By replacing N by $N \otimes M^{\vee }$ , where is the linear dual, we can assume that $M = K_{*}$ . We have a Cartan–Eilenberg spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Ext}}^{s_{0}}_{K_{*}E}(K_{*}, \operatorname{\mathrm{Ext}}^{s_{1}}_{K_{*}^{E}K}(K_{*}, N)) \implies \operatorname{\mathrm{Ext}}^{s_{0}+s_{1}}_{K_{*}K}(K_{*}, N). \end{align*}$$

The groups contributing to $\operatorname {\mathrm {Ext}}^{s}_{K_{*}K}(K_{*}, N)$ are those indexed by $s_{0}, s_{1}$ with $s_{0} + s_{1} = s$ , of which there are finitely many. For a fixed $s_{1}$ , the group $\operatorname {\mathrm {Ext}}^{s_{1}}_{K_{*}^{E}K}(K_{*}, N)$ is finite-dimensional over $K_{*}$ since both M and $K_{*}^{E}K$ are, and we can compute this $\operatorname {\mathrm {Ext}}$ -group using the cobar complex. The finiteness of $\operatorname {\mathrm {Ext}}^{s_{0}}_{K_{*}E}(K_{*}, -)$ applied to these groups follows from Corollary 5.7.

6 Milnor filtration

In this section, we describe a filtration on $K_{*}K$ , which arises from its module structure over E, which we call the Milnor filtration. We show that at odd primes, this filtration can be canonically refined to a grading which forces the Cartan–Eilenberg spectral sequence associated to the extension $K_{*}E \rightarrow K_{*}K \rightarrow K_{*}^{E}K$ to collapse.

Remark 6.1. This existence of an additional grading at $p> 2$ is a finite height analogue of the classical argument involving the Cartan–Eilenberg spectral sequence associated to $H \mathbb {F}_{p}$ (see [Reference RavenelRav03, Theorem 4.3.3]).

The Milnor filtration will be induced by a suitable filtration of the spectrum $K \otimes K$ . Before we work with such objects, we first recall some standard definitions and establish terminology.

A nonnegatively filtred spectrum is a functor , where we consider the natural numbers as a partially ordered set. If X is a spectrum, then a filtration on X is a filtred spectrum $P_{\bullet }$ together with an equivalence $\varinjlim P_{\bullet } \simeq X$ .

Remark 6.2. Note that according to our terminology, any filtred spectrum is canonically a filtration of its colimit.

To any filtration $P_{\bullet }$ , we can attach an associated nonnegatively graded spectrum

$$\begin{align*}\mathrm{gr}(P_{\bullet}) = \bigoplus_s\mathrm{gr}_{s}(P_{\bullet}) \end{align*}$$

with the degree s part defined by

where $P_{-1} = 0$ by convention. The boundary maps

$$\begin{align*}\Sigma^{-1} \mathrm{gr}_{s}(P_{\bullet}) \rightarrow P_{s-1} \rightarrow \mathrm{gr}_{s-1}(P_{\bullet}) \end{align*}$$

make $\Sigma ^{-s} \mathrm {gr}_{s}(P_{\bullet })$ into a chain complex in the homotopy category of spectra. Any filtration has a corresponding spectral sequence of signature

where the first differential is induced by the chain complex structure on the associated graded [Reference LurieLur16, Section 1.2.2]. The increasing filtration on $\pi _{*}X$ associated to this spectral sequence is given by the images of the maps $\pi _{*} P_{s} \rightarrow \pi _{*}X$ .

There is a natural tensor product on the $\infty $ -category of filtred spectra, given by Day convolution. This has the properties that

  1. (1) if $P_{\bullet }$ and $S_{\bullet }$ are filtrations of $X, Y$ , then $P_{\bullet } \otimes S_{\bullet }$ is a filtration of $X \otimes Y$ and

  2. (2) $\mathrm {gr}(P_{\bullet } \otimes S_{\bullet }) \simeq \mathrm {gr}(P_{\bullet }) \otimes \mathrm {gr}(S_{\bullet })$ , where the latter is the tensor product of graded objects.

In fact, the latter equivalence can be upgraded to an isomorphism in the category of chain complexes in the homotopy category of spectra, where we consider the latter as symmetric monoidal with the differential on the tensor product given by the usual Leibniz rule [Reference RaksitRak20, Remark 3.2.15].

Example 6.3. We will need certain special filtrations of E-modules, the main reference here being Lurie [Reference LurieLur16, Section 7.2.1], who works with simplicial objects. By the stable Dold–Kan correspondence of [Reference LurieLur16, Section 1.2.4], this is equivalent to working with filtred objects as we do.

If $P_{\bullet }$ is an E-module filtration of some M, then we say $P_{\bullet }$ is E-free if the associated simplicial object is S-free with respect to the set $S = \{ \ \Sigma ^{n} E \ | \ n \in \mathbb {Z} \ \}$ . We say it is an E-resolution if it is E-free and an S-hypercover. For precise definitions of these terms, see [Reference LurieLur16, Definition 7.2.1.2.]. The two main facts we need are that:

  1. (1) if $P_{\bullet }$ is E-free, then the associated graded E-module is levelwise free,

  2. (2) if it is a resolution, then $\pi _{*} \Sigma ^{-n} \mathrm {gr}_{n}(P_{\bullet })$ is a projective resolution of $M_{*}$ in E-modules.

Lurie shows that any E-module M admits a resolution, which is unique (as an augmented simplicial object) up to simplicial homotopy.

If $P_{\bullet }$ is an E-module resolution of M and X is an arbitrary spectrum, then $P_{\bullet } \otimes X$ is a filtration of $M \otimes X$ , and so we get a spectral sequence whose signature is readily shown to be

This is the Künneth spectral sequence which we previously mentioned in Corollary 2.12. Note that in the particular case of $X = S^{0}$ , this spectral sequence is concentrated on the $s = 0$ line, as $E_{*}$ is flat over itself, so that the filtration on the homotopy groups $M_{*}$ induced by $P_{\bullet }$ is trivial.

We are now ready to make the key definition of this section.

Definition 6.4. The Milnor filtration on $K_{*}K \simeq \pi _{*}(K \otimes K)$ is the filtration induced by the filtration $P_{\bullet } \otimes P_{\bullet }$ of $K \otimes K$ , where $P_{\bullet }$ is an E-free resolution of K as an E-module.

In fact, the above filtration is readily identified with a familiar one.

Lemma 6.5. The Milnor filtration coincides with the filtration induced by the Künneth spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Tor}}^{E_{*}}_{s, t}(K_{*}, E_{*}K) \implies K_{t+s}K. \end{align*}$$

Proof. The Künneth spectral sequence is induced by the filtration $P_{\bullet } \otimes K$ , and the obvious map $P_{\bullet } \rightarrow K$ into the constant filtration of the latter induces a comparison map $P_{\bullet } \otimes P_{\bullet } \rightarrow P_{\bullet } \otimes K$ of filtrations of $K \otimes K$ . We claim this induces an isomorphism of spectral sequences starting from the second page onwards, and hence an isomorphism of filtrations of $K_{*}K$ .

On the first pages of the corresponding spectral sequences, we are looking at the map

$$\begin{align*}\pi_{*} (\mathrm{gr}(P_{\bullet}) \otimes \mathrm{gr}(P_{\bullet})) \rightarrow \pi_{*}(\mathrm{gr}(P_{\bullet} \otimes K)), \end{align*}$$

where we have suppressed the suspensions needed to make the above into chain complexes of graded abelian groups.

Note that if M is an arbitrary E-module, then $E_{*}M \simeq E_{*}E \otimes _{E_{*}} M$ as $E_{*}E$ is flat over $E_{*}$ so that the corresponding Künneth spectral sequence collapses. It follows that since each $\mathrm {gr}(P_{\bullet })$ is levelwise free as an E-module, we can rewrite the above map on first pages of the corresponding spectral sequences as

$$\begin{align*}\pi_{*} \mathrm{gr}(P_{\bullet}) \otimes_{E_{*}} E_{*}E \otimes_{E_{*}} \pi_{*} \mathrm{gr}(P_{\bullet}) \rightarrow \pi_{*} \mathrm{gr}(P_{\bullet}) \otimes_{E_{*}} E_{*}E \otimes_{E_{*}} K_{*}. \end{align*}$$

The tensor product of the first two factors is a nonnegatively graded complex of flat $E_{*}$ -modules, so that tensoring with it preserves quasi-isomorphism. As $\mathrm {gr}_{*}(P_{\bullet }) \rightarrow K_{*}$ is a quasi-isomorphism, we deduce that so is the map on first pages, ending the argument.

Corollary 6.6. The Milnor filtration does not depend on the choice of the E-free resolution.

Proof. This is immediate from Lemma 6.5, as any two E-free filtrations $P_{\bullet }^{1}$ , $P_{\bullet }^{2}$ induce the same Künneth filtration, as $P_{\bullet }^{1} \otimes K$ and $P_{\bullet }^{2} \otimes K$ are simplicially homotopic.

Remark 6.7. By symmetry, Lemma 6.5 implies that the Milnor filtration also coincides with the filtration induced by the other Künneth spectral sequence, namely, that of signature

$$\begin{align*}\operatorname{\mathrm{Tor}}^{E_{*}}_{s, t}(K_{*}E, K_{*}) \implies K_{t+s}K. \end{align*}$$

The main advantage of using the Milnor filtration is that its definition is manifestly symmetric, so that it is easier to work with.

Note that since the Milnor filtration coincides with the Künneth one, we immediately deduce that the associated graded object is given by

$$\begin{align*}\operatorname{\mathrm{Tor}}^{E_{*}}_{*, *}(K_{*}, E_{*}K) \simeq \operatorname{\mathrm{Tor}}^{E_{*}}_{*, *}(K_{*}, K_{*}) \otimes E_{*}K, \end{align*}$$

where the additional grading comes from the external $\operatorname {\mathrm {Tor}}$ -grading. In particular, the elements of filtration zero are given by

$$\begin{align*}F_{0}^{Mil}(K_{*}K) = E_{*}K, \end{align*}$$

the image of the canonical map $E_{*}E \rightarrow K_{*}K$ . As the latter is a sub-Hopf algebroid, this suggests that the Milnor filtration is compatible with the Hopf algebroid structure. This is indeed the case, as we now show.

Lemma 6.8. The Milnor filtration on $K_{*}K$ is multiplicative.

Proof. We first claim that the multiplication map $K \otimes K \rightarrow K$ lifts to a morphism $P_{\bullet } \otimes P_{\bullet } \rightarrow P_{\bullet }$ of filtrations.

Observe that since K is an E-algebra, the multiplication factors canonically through a map $K \otimes _{E} K \rightarrow K$ . Observe that $P_{\bullet } \otimes _{E} P_{\bullet }$ is an E-free filtration of $K \otimes _{E} K$ (although not a resolution, but this is not needed). Then, since $P_{\bullet }$ is an E-module resolution of K, it follows from [Reference LurieLur16, Proposition 7.2.1.5] (where $C = K$ ) that the map $K \otimes _{E} K \rightarrow K$ of E-modules lifts to a map $P_{\bullet } \otimes _{E} P_{\bullet } \rightarrow P_{\bullet }$ of filtrations. The needed lift of $K \otimes K \rightarrow K$ is then given as composition

$$\begin{align*}P_{\bullet} \otimes P_{\bullet} \rightarrow P_{\bullet} \otimes_{E} P_{\bullet} \rightarrow P_{\bullet}, \end{align*}$$

where the first map is the canonical one to the relative tensor product.

We now claim that the multiplication on $K \otimes K$ also lifts to a map of corresponding filtrations of spectra, showing that it respects filtrations on homotopy groups. This product map is given up to homotopy by the composite

where $\sigma $ is the twist in the symmetric monoidal structure. This is lifted to a map of filtrations by

where $\widetilde {m}$ is the lift of the multiplication map constructed above. This ends the argument.

Theorem 6.9. The Milnor filtration makes $K_{*}K$ into a filtred Hopf algebroid over $K_{*}$ .

Proof. We have already checked that the Milnor filtration is preserved by multiplication on $K_{*}K$ in Lemma 6.8. Thus, we are left with comultiplication and antipode. The latter is induced by the twist map $K \otimes K$ , which can be lifted to a map of filtration by the twist on $P_{\bullet } \otimes P_{\bullet }$ , hence it preserves the filtration on homotopy groups.

We move on to comultiplication $\Delta \colon K_{*}K \rightarrow K_{*}K \otimes _{K_{*}} K_{*}K$ . This is induced by the map

where $u\colon S^{0} \rightarrow K$ is the unit and we implicitly use the Künneth isomorphism

$$\begin{align*}\pi_{*}((K \otimes K) \otimes_{K} (K \otimes K)) \simeq K_{*}K \otimes_{K_{*}} K_{*}K, \end{align*}$$

which holds in full generality since $K_{*}$ is a field.

As $P_{\bullet }$ is an E-free filtration of K, it induces a trivial filtration on $K_{*}$ , so that the unit factors through some map $S^{0} \rightarrow P_{0}$ . The latter induces a map $\widetilde {u}\colon S^{0} \rightarrow P_{\bullet }$ of filtrations, where we equip the sphere with the trivial filtration, which makes it into the monoidal unit of filtred spectra.

Consider the composite

which by construction lifts the map, inducing comultiplication. As the filtrations of $K_{*}K$ induced by $P_{\bullet } \otimes K$ and $K \otimes P_{\bullet }$ coincide with the Milnor filtration by Lemma 6.5 and Remark 6.7, we deduce that comultiplication preserves the Milnor filtration as needed.

We now show that if $p> 2$ and $K_{*}K$ is commutative—for example, if K is homotopy commutative—then the Milnor filtration can be canonically promoted to a grading. We will prove that the existence of this grading implies that the Cartan–Eilenberg spectral sequence associated to the extension $K_{*}E \rightarrow K_{*}K \rightarrow K_{*}^{E}K$ collapses.

Assume that $p> 2$ and $K_{*}K$ is commutative. We first use the Milnor filtration to describe $K_{*}K$ completely as an algebra. By Lemma 6.5, the associated graded to the Milnor filtration is given by

$$\begin{align*}\operatorname{\mathrm{Tor}}_{*, *}^{E_{*}}(K_{*}, E_{*}K) \simeq \operatorname{\mathrm{Tor}}_{*, *}^{E_{*}}(K_{*}, K_{*}) \otimes E_{*}K. \end{align*}$$

Observe that since $F_{0}^{\operatorname {\mathrm {Mil}}}(K_{*}K) \simeq E_{*}K$ is concentrated in even internal degrees, the canonical projection

$$\begin{align*}F_{1}^{\operatorname{\mathrm{Mil}}}(K_{*}K) \rightarrow \mathrm{gr}_{1}^{\operatorname{\mathrm{Mil}}}(K_{*}K) \simeq \operatorname{\mathrm{Tor}}_{1}^{E_{*}}(K_{*}, K_{*}) \otimes E_{*}K \end{align*}$$

is an isomorphism in odd internal degrees. It follows that the inclusion

$$\begin{align*}i \colon \operatorname{\mathrm{Tor}}_{1}^{E_{*}}(K_{*}, K_{*}) \hookrightarrow \operatorname{\mathrm{Tor}}_{1}^{E_{*}}(K_{*}, K_{*}) \otimes E_{*}K \end{align*}$$

can be uniquely lifted to a map

$$\begin{align*}j \colon \operatorname{\mathrm{Tor}}_{1}^{E_{*}}(K_{*}, K_{*}) \rightarrow F_{1}^{\operatorname{\mathrm{Mil}}} K_{*}K. \end{align*}$$

Since $\operatorname {\mathrm {Tor}}_{*, *}^{E_{*}}(K_{*}, K_{*})$ is an exterior algebra on elements of external degree one, when $p> 2$ , this $\operatorname {\mathrm {Tor}}$ -algebra is a free commutative $K_{*}$ -algebra on the vector space $\operatorname {\mathrm {Tor}}_{1, *}$ . If $K_{*}K$ is commutative, it follows that the above lift j uniquely extends to a map of $K_{*}$ -algebras

$$\begin{align*}\operatorname{\mathrm{Tor}}_{*, *}^{E_{*}}(K_{*}, K_{*}) \rightarrow K_{*}K \end{align*}$$

with the following property:

Proposition 6.10. Let $p> 2$ , and assume that $K_{*}K$ is commutative. Then, the induced map of $E_{*}K$ -algebras

(6.11) $$ \begin{align} \operatorname{\mathrm{Tor}}^{E_{*}}_{*, *}(K_{*}, K_{*}) \otimes_{K_{*}} E_{*}K \rightarrow K_{*}K \end{align} $$

is an isomorphism.

Proof. By construction, the above map is surjective on the associated graded of $K_{*}K$ with respect to the Milnor filtration. Thus, it is surjective by an inductive argument, and as a surjective map of free $E_{*}K$ -modules of the same rank, it must be an isomorphism.

As a consequence of Proposition 6.10, $K_{*}K$ inherits an additional external grading from the grading of $\operatorname {\mathrm {Tor}}$ -groups. This grading can be made explicit, as in the following definition.

Definition 6.12. Let $p> 2$ , and assume that $K_{*}K$ is commutative. Then, the Milnor grading on $K_{*}K$ is the unique algebra grading, such that

  1. (1) elements of Milnor filtration zero are of Milnor degree zero and

  2. (2) odd internal degree elements of Milnor filtration at most one are of Milnor degree one.

Lemma 6.13. The Milnor grading is well-defined.

Proof. This is immediate from Proposition 6.10, as the external grading on the algebra tensor product on $\operatorname {\mathrm {Tor}}_{*, *}^{E_{*}}(K_{*}, K_{*}) \otimes _{K_{*}} E_{*}K$ is uniquely determined by which elements are of degrees zero and one.

Remark 6.14. The increasing filtration associated to the Milnor grading is exactly the Milnor filtration. Thus, this grading can be considered as a refinement of the latter canonical filtration, which exists at all primes and with no assumptions on commutativity.

Theorem 6.15. Let $p> 2$ , and assume that $K_{*}K$ is commutative. Then, the Milnor grading on $K_{*}K$ is compatible with comultiplication and antipode, making it into a bigraded Hopf algebroid.

Proof. As $K_{*}K$ is generated as an algebra by elements in Milnor degrees zero and one, it is enough to check that these two degrees are preserved. The subspace of elements of Milnor degree at most one coincides with elements of filtration at most one, which get preserved by comultiplication and antipode by Theorem 6.9.

Since the ones in Milnor degree zero are precisely those of even internal degree, and the ones in Milnor degree one are exactly the ones of odd internal degree, we deduce that each degree gets preserved separately by both comultiplication and antipode.

Remark 6.16. To see what goes wrong if $p = 2$ , observe that even if $K_{*}K$ were commutative, odd degree elements do not have to square to zero, and so there need not be a multiplicative extension of the canonical map $\operatorname {\mathrm {Tor}}_{1}^{E_{*}}(K_{*}, K_{*}) \rightarrow K_{*}K$ to a map on the whole $\operatorname {\mathrm {Tor}}$ -algebra.

One can try to define the Milnor grading at $p = 2$ directly similarly to Definition 6.12, by declaring that elements in Milnor degree s are the s-fold products of those in Milnor degree one. This is bound to fail; the calculations of Würgler in the case of the minimal Morava K-theory given in Section 3 show that the elements $\tau _{i}$ of Milnor degree one square to nonzero elements of Milnor degree zero.

Theorem 6.17. Suppose that $p> 2$ and that $K_{*}K$ is commutative. Then, the Cartan–Eilenberg spectral sequence associated to the extension

$$\begin{align*}K_{*}E \rightarrow K_{*}K \rightarrow K_{*}^{E}K \end{align*}$$

collapses on the second page, inducing a canonical isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}_{K_{*}K}(K_{*}, K_{*}) \simeq \operatorname{\mathrm{Ext}}_{K_{*}E}(K_*,\operatorname{\mathrm{Ext}}_{K_{*}^{E}K}(K_{*}, K_{*})). \end{align*}$$

Proof. Under the given assumptions, $K_{*}K$ is bigraded using its internal grading and the Milnor grading of Definition 6.12. This grading is compatible with the above extension, with all of $K_{*}E$ of Milnor degree zero.

As $K_{*}^{E}K \simeq \Lambda _{K_{*}}(V)$ as Hopf algebras, where V is the $K_{*}$ -vector subspace of primitive elements, we have

$$\begin{align*}\operatorname{\mathrm{Ext}}^{*, *, *}_{K_{*}^{E}K}(K_{*}, K_{*}) \simeq \operatorname{\mathrm{Sym}}_{K_{*}}(V^{\vee}), \end{align*}$$

an isomorphism with the symmetric algebra. Here, $V^{\vee }$ is of homological degree one and Milnor degree one, and so the whole above $\operatorname {\mathrm {Ext}}$ -algebra is concentrated on the plane of elements for which the Milnor degree is equal to the homological one.

Since the Cartan–Eilenberg differentials lower the homological degree and preserve the Milnor degree, we deduce that they are all zero. This gives an isomorphism as above up to passing to associated graded to the homological filtration, as the extension problems all get trivialised by the additional grading.

Part 2. The K -based Adams spectral sequence

In this part, we study the Adams spectral sequence based on a Morava K-theory K at arbitrary height n and prime p, constructed as part of a finite height analogue of Miller’s square of spectral sequences. In particular, we establish its (perhaps surprisingly) good convergence properties and identify it with the filtration by powers spectral sequence, at least for sufficiently large primes p. We then conclude this part with an illustration of the spectral sequence at heights 1 and odd primes, already exhibiting the existence of arbitrary long differentials.

Remark 6.18 (Adams spectral sequence based on Milnor modules).

We do not proceed in this way, but one can phrase the K-based Adams spectral sequence entirely in terms of absolute Milnor modules, following Miller’s observation that the Adams spectral sequence is determined by the class of $K_{*}$ -injective maps.

To see this, notice that the restricted Yoneda embedding, followed by a sheafification, gives a symmetric monoidal functor

$$\begin{align*}y\colon \operatorname{\mathrm{Sp}} \rightarrow \operatorname{\mathrm{Mil}}_{abs} \end{align*}$$

which can be considered a Milnor modules-valued homology theory. That is, the functor y takes cofibre sequences to exact sequences, preserves arbitrary direct sums and takes the suspension in spectra to the distinguished autoequivalence of Milnor modules induced by the suspension functor on $\operatorname {\mathrm {Sp}}^{fin}$ .

By construction, any injective object in Milnor modules can be lifted to a representing object in spectra, and this allows one to construct a ‘y-based’ Adams spectral sequence based on injectives, where the $E_{2}$ -terms are canonically given by $\operatorname {\mathrm {Ext}}$ -groups in absolute Milnor modules [Reference Patchkoria and PstragowskiPP21]. Through the equivalence of Proposition 4.12, this spectral sequence is canonically isomorphic to the K-based Adams spectral sequence for any choice of Morava K-theory.

7 Convergence of the K-based Adams spectral sequence

In this short section, we prove that the K-based Adams spectral sequence is conditionally convergent for any K-local spectrum, and it converges completely in the dualisable case.

Remark 7.1. As observed in Remark 6.18, the K-based Adams spectral sequence depends only on the choice of the prime and the height. However, this independence from choices will not be needed in this section, as the arguments we use apply equally well to any Morava K-theory.

By standard arguments, the K-based Adams spectral sequence is isomorphic to the totalisation spectral sequence obtained by mapping into the canonical K-Adams resolution

$$\begin{align*}X \rightarrow K \otimes X \rightrightarrows K \otimes K \otimes X \Rrightarrow \ldots .\end{align*}$$

Thus, it follows that the K-based Adams spectral sequence converges to the homotopy of the K-nilpotent completion of X:

Since the totalisation is K-local as a limit of K-local spectra, there is a canonical comparison map from the K-localisation of X. Our first task is to determine when this map is an equivalence.

Proposition 7.2. For any spectrum X, the K-nilpotent completion of X is equivalent to the K-localisation of X; that is, the canonical map

(7.3) $$ \begin{align} L_{K}X \rightarrow \operatorname{\mathrm{Tot}}(K^{\otimes \bullet+1} \otimes X) \end{align} $$

is an equivalence.

Proof. Since both sides are K-local, it is enough to show that this map is a $K_{*}$ -isomorphism. The latter can be checked after tensoring with any non-K-acyclic spectrum as $K_{*}$ is a field, so that we have the Künneth isomorphism, and tensoring with a nonzero $K_{*}$ -vector space reflects isomorphisms.

After tensoring with a finite spectrum $F(n)$ of type n, the above map becomes

$$\begin{align*}L_{K}(X \otimes F(n)) \rightarrow \operatorname{\mathrm{Tot}}(K^{\otimes \bullet+1} \otimes X \otimes F(n)), \end{align*}$$

as both sides of (7.3) define exact functors in X and so commute with tensoring with a finite spectrum. Thus, it is enough to check the result holds for $X \otimes F(n)$ .

The proof of the smash product theorem in [Reference RavenelRav92, Chapter 8] shows that $S^0$ is E-prenilpotent; that is, $L_ES^0 \in \operatorname {\mathrm {Thick}}^{\otimes }(E)$ , where $\operatorname {\mathrm {Thick}}^{\otimes }(Y)$ denotes the smallest full subcategory of which contains Y, is thick and is closed under smashing with arbitrary objects in . It follows that

$$\begin{align*}L_{K}F(n) \simeq L_E F(n) \in \operatorname{\mathrm{Thick}}^{\otimes}(E\otimes F(n)) \subseteq \operatorname{\mathrm{Thick}}^{\otimes}(K). \end{align*}$$

In other words, $F(n)$ is K-prenilpotent. By definition, $X \otimes F(n)$ is thus also K-prenilpotent for all . Therefore, Bousfield’s theorem [Reference BousfieldBou79, Theorem 6.10] applies to provide an equivalence $L_{K}(X \otimes F(n)) \simeq \operatorname {\mathrm {Tot}} (K^{\otimes \bullet +1} \otimes X \otimes F(n))$ , which is what we wanted.

If $X, Y$ are spectra, then by applying $[Y, -]$ to the canonical K-Adams resolution of X, we obtain the Adams spectral sequence as the totalisation spectral sequence. Since $K_{*}$ is a field, $K_{*}Y$ is projective over the base ring, so that by standard arguments, the resulting spectral sequence has signature

$$\begin{align*}E_2^{s,t}(Y, X) \simeq \operatorname{\mathrm{Ext}}_{K_*K}^{s,t}(K_*Y,K_*X) \implies [Y, L_{K}X]^{t-s}. \end{align*}$$

Indeed, if we use the canonical Adams resolution, then the first page of the Adams spectral sequence is given by the cobar complex, which in the projective case computes the $\operatorname {\mathrm {Ext}}$ -groups in comodules [Reference RavenelRav03, Corollary A.1.2.12].

Corollary 7.4. For any K-local spectrum X and any Y, the K-based Adams spectral sequence converges conditionally in the sense of Boardman to $[Y, L_{K}X]$ .

Proof. The totalisation spectral sequence is the spectral sequence induced by the tower of partial totalisations. Conditional convergence to $[-, L_{K}X]$ in the sense of Boardman is equivalent to the natural map from $L_{K}X$ into the limit of this tower being an equivalence, so that the statement follows from Proposition 7.2.

Let us write $E_{r}^{*, *}(Y, X)$ for the r-th page of the K-based Adams spectral sequence converging conditionally to $[Y, L_{K}X]$ , so that we have $E_{2}^{s, t}(Y, X) \simeq \operatorname {\mathrm {Ext}}_{K_{*}K}^{s, t}(K_{*}Y, K_{*}X)$ . The differentials in this spectral sequence are of the form

$$\begin{align*}d_r\colon E_r^{s,t}(Y, X) \to E_r^{s+r,t+r-1}(Y, X). \end{align*}$$

In particular, for $r>s$ , there are inclusions $E_{r+1}^{s,t}(Y, X) \subseteq E_{r}^{s,t}(Y, X)$ , and we write

$$\begin{align*}E_{\infty}^{s,t}(Y, X) = \operatorname{\mathrm{lim}}_rE_{r}^{s,t}(Y, X). \end{align*}$$

Let $F^*[Y,L_{K}X]_*$ denote the filtration on $[Y,L_{K}X]_*$ induced by the spectral sequence. Following Bousfield [Reference BousfieldBou79, Section 6], we say that the K-based Adams spectral sequence for X converges completely if the canonical maps

$$ \begin{align*} [Y,L_{K}X]_* \twoheadrightarrow \operatorname{\mathrm{lim}}_s [Y,L_{K}X]_* / F^s[Y,L_{K}X]_* \end{align*} $$

and

$$ \begin{align*} F^s[Y,L_{K}X]_* / F^{s+1}[Y,L_{K}X]_* \hookrightarrow E_{\infty}^{s,s+*}(Y, X) \end{align*} $$

are isomorphisms. By the work of Bousfield, see [Reference BousfieldBou79, Proposition 6.3], this is equivalent to the condition that $\operatorname {\mathrm {lim}}_{r>s}^1E_{r}^{s,t}(Y, X)$ vanishes.

Proposition 7.5. The K-based Adams spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Ext}}_{K_*K}^{s,t}(K_*Y,K_*X) \implies [Y, L_{K}X]^{t-s} \end{align*}$$

converges completely for any spectra X and Y with $K_{*}X$ and $K_{*}Y$ finite-dimensional.

Proof. By Theorem 5.10, the groups in the $E_{2}$ -term are all finite. Therefore, the system

$$\begin{align*}(E_r^{s,t}(Y, X))_{r>s} \end{align*}$$

is Mittag-Leffler, so that Bousfield’s convergence criterion [Reference BousfieldBou79, Proposition 6.3] applies.

Remark 7.6. For a spectrum X, the homology $K_{*}X$ being finite-dimensional is equivalent to X being K-locally dualisable (see [Reference Hovey and StricklandHS99, Theorem 8.6]).

Remark 7.7. In general, the K-based Adams spectral sequence may fail to converge completely in the sense of Bousfield (see Example 10.7).

8 The finite height Miller square

In his seminal paper [Reference MillerMil81] on relations between Adams spectral sequences, Miller uses the relationship between the Adams–Novikov and classical Adams spectral sequences to prove the telescope conjecture at height 1 and odd primes. In this section, we apply his axiomatic framework to the case of Lubin–Tate and Morava K-theory spectra.

In Miller’s framework, one starts with a map $A \rightarrow B$ of homotopy ring spectra; that is, an arrow in the category $\operatorname {\mathrm {Alg}}(\operatorname {\mathrm {ho}}(\operatorname {\mathrm {Sp}}))$ . In this context, it is not hard to show that a map $X \rightarrow Y$ of spectra which is A-monic, in the sense that $A \otimes X \rightarrow A \otimes Y$ is a split inclusion, is also B-monic. Thus, any B-injective spectrum is also A-injective (see [Reference MillerMil81, Lemma 2.1]).

Definition 8.1 (Miller).

A spectrum X is $(A, B)$ -primary if there exists an A-Adams resolution $X \rightarrow I^{\bullet }$ , such that for each ${m}$ , the B-Adams spectral sequence computing $\pi _{*} I^{m}$ converges and collapses on the second page.

When X is $(A, B)$ -primary, Miller constructs a square of spectral sequences

which we now explain. The terms $E_{A}^{2}(X), E^{2}_{B}(X)$ form the second pages of the relevant Adams spectral sequences, and the bottom two arrows are the corresponding Adams spectral sequences.

The construction of the other two spectral sequences is more involved, but let us briefly recall the arguments of Miller. Observe that $E^{2}_{A}(X)$ arises as homology of the cochain complex $\pi _{*} I^{\bullet }$ , where $I^{\bullet }$ is an A-Adams resolution as in Definition 8.1. As this cochain complex is given by homotopy groups, it has an additional filtration given by the B-Adams filtration. By definition, the term $E^{2}_{A, B}(X)$ is the cohomology of the associated graded of $\pi _{*} I^{\bullet }$ with respect to this filtration, and the top left arrow is the associated cohomology of filtred complex spectral sequence, which Miller calls the May spectral sequence.

If X is primary in the sense of Definition 8.1, the cohomology $E^{2}_{A, B}(X)$ of the associated graded of $\pi _{*} I^{\bullet }$ is the same as the cohomology of the complex $E^{2}_{B}(I^{\bullet })$ consisting of the B-Adams $E_{2}$ -pages of the spectra $I^{\bullet }$ . As all A-split maps are B-split, these $E_{2}$ -pages are related by long exact sequences and can be collected into an $E_{1}$ of an exact couple using that $I^{\bullet }$ is a resolution of X, yielding a spectral sequence computing $E^{2}_{B}(X)$ . This is the spectral sequence in the top right corner, which Miller calls the Mahowald spectral sequence.

Remark 8.2. Miller proves that the above diagram of spectral sequences is commutative in the sense that, after making appropriate choices, the $d_{2}$ -differentials in the May spectral sequence can be identified with $d_{2}$ -differentials in the B-Adams spectral sequence [Reference MillerMil81, Theorem 4.2]. In the case of Morava K-theory and under the assumption that the prime is large enough compared to the height, we generalise this result to higher differentials in Proposition 9.13.

Let us give an explicit description of these spectral sequences for Lubin–Tate spectra and Morava K-theories. Note that in this case, the E-based Adams spectral sequence computes the E-local homotopy groups, which are quite different from the K-local ones. Thus, to get a commutative square, we should work internally to K-local spectra.

Our first goal is to show that the K-based Adams spectral sequence has a particularly simple form for E-modules with flat homotopy groups. To do so, we will reduce to the profree case using the work of Hovey [Reference HoveyHov04c].

Before we proceed, let us recall that the completion functor is neither left nor right exact, but it has left derived functors $L_{s}\colon \operatorname {\mathrm {Mod}}_{E_{*}} \rightarrow \operatorname {\mathrm {Mod}}_{E_{*}}$ . For more properties of these functors, see [Reference Hovey and StricklandHS99, Appendix B] or [Reference Barthel and FranklandBF15, Appendix A].

Lemma 8.3. Let $M_*$ be an $E_{*}$ -module, such that $\operatorname {\mathrm {Tor}}_{s}^{E_{*}}(M_{*}, K_{*}) = 0$ for $s> 0$ ; for example, $M_*$ can be flat over $E_*$ . Then, the completion $(M_{*})^{\vee }_{\mathfrak {m}}$ is profree.

Proof. This is proven by Hovey in [Reference HoveyHov04c, Proposition 1.2].

Lemma 8.4. Let M be an E-module such that $M_{*}$ is flat over $E_{*}$ . Then, the K-localisation map $M \rightarrow L_{K} M$ induces an isomorphism $\pi _{*} L_{K} M \simeq (M_{*})^{\vee }_{\mathfrak {m}}$ with the completion.

Proof. Hovey constructs for any E-module M a strongly convergent spectral sequence of signature

$$\begin{align*}L_{s} M_{t} \rightarrow \pi_{t+s} L_{K} M. \end{align*}$$

In the present case, the spectral is concentrated on the zero line by Lemma 8.3, hence, the spectral sequence collapses, inducing the needed isomorphism.

Corollary 8.5. Let M be an E-module, such that $M_{*}$ is flat over $E_*$ . Then, $L_{K}M$ is equivalent as an E-module to the K-localisation of a direct sum of copies of E.

Proof. We have $\pi _{*} L_{K} M \simeq (M_{*})^{\vee }_{\mathfrak {m}}$ by Lemma 8.4 and $(M_{*})^{\vee }_{\mathfrak {m}}$ is profree by Lemma 8.3. Choosing pro-generators of the latter induces a map $L_{K}(\bigoplus E) \rightarrow L_{K}M$ from a direct sum of shifts of E which is an equivalence by inspection of homotopy groups.

Proposition 8.6. If M is an E-module, such that $M_{*}$ is $E_{*}$ -flat, then the K-Adams filtration on $M_{*}$ is the $\mathfrak {m}$ -adic one and the K-based Adams spectral sequence for M converges completely to and collapses on the second page.

Proof. By flatness, we have $\pi _{*} L_{K}M \simeq (M_{*})^{\vee }_{\mathfrak {m}}$ . Since the $\mathfrak {m}$ -adic filtration on $M_{*}$ is induced by that of completion, we can replace M by its K-localisation. In this case, M is K-locally equivalent to a direct sum of E by Corollary 8.5. As the Adams spectral sequence of a direct sum is a direct sum of spectral sequences, we can assume that $M = E$ .

We have a base-change isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}_{K_{*}K}(K_{*}E, K_{*}) \simeq \operatorname{\mathrm{Ext}}_{K_{*}^{E}K}(K_{*}, K_{*}) \end{align*}$$

and, by Proposition 5.8, a further isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}_{K_{*}^{E}K}(K_{*}, K_{*}) \simeq K_{*} \otimes_{\kappa} \operatorname{\mathrm{Sym}}_{\kappa}^{*} (\mathfrak{m} / \mathfrak{m}^{2}). \end{align*}$$

Since $E_{0}$ is regular, $\operatorname {\mathrm {Sym}}_{\kappa }^{*} (\mathfrak {m} / \mathfrak {m}^{2})$ can be identified with the associated graded to the $\mathfrak {m}$ -adic filtration on $E_{0}$ .

We deduce from the above that the $E_{2}$ -term of the K-based Adams for E is abstractly isomorphic to the associated graded of the $\mathfrak {m}$ -adic filtration on $E_{*}$ . Moreover, since the $E_{2}$ -term is concentrated in even Adams degree, we deduce that the Adams spectral sequence collapses.

We are left with showing that the K-based Adams filtration on $E_{*}$ coincides with the $\mathfrak {m}$ -adic one. Observe that since $E \rightarrow K$ is a $K_{*}$ -monomorphism by Proposition 2.13, the elements of positive Adams filtration are precisely given by $\mathfrak {m} E_{*} = \mathrm {ker}(E_{*} \rightarrow K_{*})$ .

Using compatibility of the Adams filtration with products, we deduce that any element of $\mathfrak {m}^{n} E_{*}$ is of Adams filtration at least n. Thus, one filtration is contained in the other. As their associated gradeds have the same dimension over $K_{*}$ by what was said above, we deduce that the two filtrations must coincide, as needed.

Proposition 8.7. Let X be a spectrum, such that is profree; for example, such that $E_{*}X$ is flat. Then, X is $(E, K)$ -primary in the K-local category.

Proof. The implication that $E_{*}X$ flat implies $E_{*}^{\vee }X$ profree is a combination of Lemma 8.3 and Proposition 8.6.

Since $E_{*}E$ is flat over $E_{*}$ , this, in particular, implies that $E_{*}^{\vee } E$ is profree, which can be also proven directly using evenness (see [Reference Hovey and StricklandHS99, Theorem 8.6]). It follows (as in [Reference Barthel and HeardBH16, Corollary 1.24], for example) that

$$\begin{align*}\pi_{*} L_{K}(E^{\bullet} \otimes X) \simeq (E_{*}^{\vee}E)^{\otimes^{\vee}_{E_{*}} \bullet-1} \otimes^{\vee}_{E_{*}} E_{*}^{\vee} X, \end{align*}$$

where on the right-hand side we have the completed tensor products, which are again profree. This together with Proposition 8.6 implies that the standard K-local E-based Adams resolution

satisfies the primarity condition.

If $E_{*}^{\vee }X$ is profree, then the $E_{1}$ -page of the K-local E-based Adams spectral sequence is given by the cobar complex

$$\begin{align*}\pi_{*} L_{K}(E^{\bullet} \otimes X) \simeq (E_{*}^{\vee}E)^{\otimes^{\vee}_{E_{*}} \bullet-1} \otimes_{E_{*}} E_{*}^{\vee} X. \end{align*}$$

It follows from Proposition 8.6 that the K-Adams filtration on these homotopy groups coincides with the filtration by powers of the maximal ideal $\mathfrak {m}$ ; this is the ‘filtration by powers’ appearing in the title. This has the following consequence.

Corollary 8.8. If $E_{*}^{\vee }X$ is profree, then Miller’s May spectral sequence associated to $(E, K)$ coincides with the spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Ext}}_{E_{*}^{\vee}E}^{s,t}(E_{*}, \bigoplus \mathfrak{m}^{n}/\mathfrak{m}^{n+1} E_{*}^{\vee}X) \implies \operatorname{\mathrm{Ext}}_{E_{*}^{\vee}E}^{s,t}(E_{*}, E^{\vee}_{*}X) \end{align*}$$

obtained by filtring $E_{*}^{\vee }X$ by powers of the maximal ideal; that is, by $\mathfrak {m}^{n} E_{*}^{\vee }X$ .

Proof. Since Miller’s May spectral sequence is induced by the K-Adams filtration on the homotopy groups of the K-local E-Adams resolution, this is a consequence of Proposition 8.6, as under the above assumption all of the spectra in the resolution are profree.

Remark 8.9. The identification of the $E_{2}$ -page of the K-local E-based Adams spectral sequence is somewhat subtle. However, in the case where $E_{*}^{\vee }X$ is profree, it follows from [Reference Barthel and HeardBH16] that it acquires a structure of a suitably complete comodule over $E_{*}^{\vee }E$ and that the $E_{2}$ -page is given by the $\operatorname {\mathrm {Ext}}$ -groups in comodules as above.

We deduce that the K-local Miller square associated to $(E, K)$ is of the form

(8.10)

whenever $E^{\vee }_{*}X$ is profree. This leaves the question of identifying the Mahowald spectral sequence, which is not too difficult.

Proposition 8.11. If $E_{*}^{\vee }X$ is profree, then Miller’s Mahowald spectral sequence based on $(E, K)$ can be identified with the Cartan–Eilenberg spectral sequence associated to the extension of Hopf algebroids

$$\begin{align*}K_{*}E \rightarrow K_{*}K \rightarrow K_{*}^{E}K. \end{align*}$$

Proof. Taking the standard K-local E-Adams resolution

$$\begin{align*}X \rightarrow L_{K}(E \otimes X) \rightarrow L_{K}(E \otimes \overline{E} \otimes X) \rightarrow \ldots \end{align*}$$

and applying K-homology gives the long exact sequence of comodules of the form

$$\begin{align*}K_{*}X \rightarrow K_{*}E \otimes K_{*}X \rightarrow K_{*}E \otimes_{K_{*}} \overline{K_{*}E} \otimes_{K_{*}} K_{*}X \rightarrow \ldots. \end{align*}$$

Applying $\operatorname {\mathrm {Ext}}_{K_{*}K}(K_{*}, -)$ to the above leads to an exact couple which yields the Mahowald spectral sequence.

Note that from the description of the $E_{1}$ -term, we see that this is just the $K_{*}E$ -based Adams spectral sequence in the derived category of $K_{*}K$ -comodules, sometimes called the Margolis–Palmieri spectral sequence. This is known to be isomorphic to the Cartan–Eilenberg spectral sequence associated to the extension (see [Reference BelmontBel20, Theorem 4.2]).

Remark 8.12. We have shown in Theorem 6.17 that if $p> 2$ , then the Cartan–Eilenberg spectral sequence computing $\operatorname {\mathrm {Ext}}_{K_{*}K}(K_{*}, K_{*})$ collapses on the second page. It follows from the isomorphism of Proposition 8.11 that the same is true for Miller’s $(E,K)$ -Mahowald spectral sequence associated to $X = S^{0}$ .

Remark 8.13. Note that applying Proposition 8.11 to the starting terms of the respective spectral sequences implies, in particular, that

$$\begin{align*}\operatorname{\mathrm{Ext}}_{E_{*}^{\vee}E}(E_{*}, \bigoplus \mathfrak{m}^{n}/\mathfrak{m}^{n+1} E_{*}) \simeq \operatorname{\mathrm{Ext}}_{E_{*}K}(K_{*}, \operatorname{\mathrm{Ext}}_{K_{*}^{E}K}(K_{*}, K_{*})). \end{align*}$$

This can be proven directly, without resorting to Miller’s work, using Hopkins and Lurie’s calculation of the cohomology of $K_{*}^{E}K$ , which we stated as Proposition 5.8. The key is that since $E_{0}$ is regular, we have $\operatorname {\mathrm {Sym}}_{\kappa }(\mathfrak {m} / \mathfrak {m}^{2}) \simeq \bigoplus \mathfrak {m}^{n} / \mathfrak {m}^{n+1}$ .

Remark 8.14. If we again pick $E = E_{n}$ , the Lubin–Tate spectrum associated to the Honda formal group law of height n over $\mathbb {F}_{p^{n}}$ , then the relevant $\operatorname {\mathrm {Ext}}$ -groups appearing in the Miller square can be described in terms of the cohomology of the Morava stabiliser group (see [Reference Barthel and HeardBH16, Theorem 4.3]). Keeping this choice of E in mind, we can rewrite the Miller square as

Remark 8.15. In the important case of $(MU, H \mathbb {F}_{p})$ , the Miller square can also be described explicitly (see, for example [Reference Gheorghe, Wang and XuGWX21]). In this context, the Miller square foreshadows the later development of the $\mathrm {C}\tau $ -philosophy of Gheorghe, Isaksen, Wang and Xu which applied motivic methods to breakthrough results in stable homotopy groups of spheres [Reference Isaksen, Wang and XuIWX20].

9 The K-based Adams spectral sequence at large primes

It is well-known that if p is large compared to the height, then the E-based Adams–Novikov spectral sequence for the K-local sphere collapses. As the same is true for the Mahowald spectral sequence, as we have shown in Remark 8.12, we deduce that under these assumptions, two of the sides of the Miller square of (8.10) represent collapsing spectral sequences.

It is then only natural to expect that the other two sides can be identified up to regrading; in this section, we show that this is indeed the case. More precisely, we show that if $2p-2> n^{2}+n+1$ , then the K-based Adams spectral sequence for the sphere is isomorphic to the filtration by powers spectral sequence

$$\begin{align*}\mathrm{H}^{*}(\mathbb{G}_{n}, \bigoplus \mathfrak{m}^{n}/\mathfrak{m}^{n+1}) \implies \mathrm{H}^{*}(\mathbb{G}_{n}, E_{*}), \end{align*}$$

which we can identify with Miller’s May spectral sequence by Corollary 8.8.

Remark 9.1. Note that a result of Miller [Reference MillerMil81, Theorem 4.2] relates the $d_{2}$ -s in the May and K-based Adams spectral sequence, at all primes and heights. Our first approach to this problem was to try to push Miller’s methods further into higher differentials, hoping that the collapses of the other two spectral sequences in the square would simplify the situation. This approach was unsuccessful, and below we use quite different methods.

Remark 9.2. While we show in this section that at large primes the K-based Adams spectral sequence admits an algebraic description, it never collapses for $n>0$ , unlike the Adams–Novikov spectral sequence. Indeed, the element $v_{n} = u^{p^{n}-1} \in \operatorname {\mathrm {Ext}}^{0, 2p^{n}-2}_{K_{*}K}(K_{*}, K_{*})$ is never a permanent cycle, as the K-local sphere is of type $0$ and so cannot admit a $v_{n}$ -periodic map.

To prove our comparison result, we use an algebraicity result for homotopy categories of E-local spectra at large primes due to the second author, strengthened in recent work with Patchkoria [Reference Patchkoria and PstragowskiPP21], which compares it to the following algebraic construction.

Notation 9.3. Let us write

for the derived $\infty $ -category of the abelian category of comodules. This is a symmetric monoidal stable $\infty $ -category, with monoidal unit given by $E_{*}$ itself, considered as a chain complex concentrated in degree zero. The unit defines for any

its homotopy groups

Notice that the homotopy groups are bigraded, since the abelian category of $E_{*}E$ -comodules has an internal grading. This endows the derived $\infty $ -category with two gradings,

  1. (1) the homological one given by the suspension and corresponding above to s and

  2. (2) the internal one induced from the grading shift functor on $\operatorname {\mathrm {Comod}}_{E_*E}$ and corresponding above to t.

In the special case of X being a comodule, considered as an object of the heart, these homotopy groups encode the $E_{2}$ -term of the E-based Adams spectral sequence in the $\infty $ -category of spectra.

Definition 9.4. The periodicity algebra $P(E_{*})$ is the $\mathbf {E}_{\infty }$ -algebra in determined by the commutative algebra

$$\begin{align*}E_{*}[\tau^{\pm 1}], \text{where } | \tau | = (1, -1) \end{align*}$$

in chain complexes of comodules, equipped with the zero differential.

Notation 9.5. For brevity, let us write

The following result shows that modules over the periodicity algebra give an algebraic model for the homotopy category of E-local spectra.

Theorem 9.6. If $2p-2> n^{2}+n$ , there exists an equivalence

of homotopy categories of E-local spectra and $P(E_{*})$ -modules which is moreover compatible with homology functors in the sense that the following diagram commutes

Proof. This is proven under the assumption $2p-2> 2(n^{2}+n)$ in the second author’s thesis [Reference PstragowskiPst18]. The bound was improved to the one given above in joint work with Patchkoria [Reference Patchkoria and PstragowskiPP21].

Remark 9.7. Note that as an $\mathbf {E}_{1}$ -algebra in , the connective cover of the periodicity algebra $P(E_{*})$ can be identified with the free $\mathbf {E}_{1}$ -algebra on the object $\Sigma E_{*}[-1]$ , and so is uniquely determined by its homology groups.

The category of modules over $P(E_{*})$ (considered only as a stable $\infty $ -category) can be identified with the subcategory of modules over the connective cover spanned by those modules on which $\tau $ acts invertibly. Thus, to define the target of the equivalence of Theorem 9.6, it is not strictly necessary to work with algebras in chain complexes as in Definition 9.4, but we do so out of convenience.

Remark 9.8. For any $M, N \in \operatorname {\mathrm {Mod}}_{P(E_{*})}$ , we have an Adams spectral sequence of signature

$$\begin{align*}\operatorname{\mathrm{Ext}}^{s, t}(\mathrm{H}_{0}(M), \mathrm{H}_{0}(N)) \implies [M, N]_{t-s}, \end{align*}$$

where on the right-hand side, we have homotopy classes of maps of $P(E_{*})$ -modules.

This observation, due to Franke [Reference FrankeFra], is the starting point for the comparison of $\operatorname {\mathrm {Mod}}_{P(E_{*})}$ to the E-local category. The general form of Franke’s conjecture implies that all stable $\infty $ -categories admitting a suitably convergent Adams-type spectral sequence of this signature must have equivalent homotopy categories [Reference Patchkoria and PstragowskiPP21].

One of the advantages of $P(E_{*})$ -modules over E-local spectra is the existence of the free module functor

(also called the periodicisation) which is cocontinuous and symmetric monoidal. The homotopy groups of free modules can be understood explicitly, as the following shows.

Remark 9.9. Since the periodicity algebra is a sum of shifts of a unit as an object of the derived $\infty $ -category, the homotopy groups of the free module are simple to understand. More precisely, for any

, we have

As a consequence, whenever a $P(E_{*})$ -module can be written as a periodicisation of some M as above, its homotopy groups acquire an additional grading. Note that any given module can be written as a periodicisation in many different ways, and this additional grading depends on that choice.

Our plan is to use Theorem 9.6 to compare the K-based Adams spectral sequence in E-local spectra to the one in its algebraic model, and subsequently give an explicit description of the latter in terms of filtration by powers.

Lemma 9.10. Let X be either the E-local sphere or a Morava K-theory; that is, $X = S^{0}_{E}$ or $X = K$ . Then, there exists a canonical isomorphism

$$\begin{align*}\phi(X) \simeq P(E_{*}) \otimes_{E_{*}} E_{*}X, \end{align*}$$

in $h \operatorname {\mathrm {Mod}}_{P(E_{*})}$ , where $\phi $ is the algebraicity equivalence of Theorem 9.6.

Proof. It will be convenient to work here with the Johnson-Wilson homology, the p-local Landweber exact homology theory with

$$\begin{align*}\pi_{*}E(n) \simeq \mathbb{Z}_{(p)}[v_{1}, \ldots, v_{n-1}, v_{n}^{\pm 1}]. \end{align*}$$

Both this ring and $E(n)_{*}E(n)$ are concentrated in degrees divisible by $2p-2$ , which is a key ingredient in the construction of the equivalence $\phi $ [Reference PstragowskiPst18, Section 2].

Choosing coordinates for the Quillen formal group over $E_{*}$ , such that $v_{i} = 0$ for $i> n$ , we obtain a classifying map $E(n)_{*} \rightarrow E_{*}$ which is faithfully flat, and hence

$$\begin{align*}E_{*}X \simeq E_{*} \otimes_{E(n)_{*}} E(n)_{*}X. \end{align*}$$

The induced functor $\operatorname {\mathrm {Comod}}_{E(n)_{*}E(n)} \rightarrow \operatorname {\mathrm {Comod}}_{E_{*}E}$ is an equivalence of categories by a result of Hovey and Strickland [Reference Hovey and StricklandHS05a].

Now suppose that X is a spectrum with $E(n)_{*}X$ concentrated in degrees divisible by $2p-2$ . Since $\phi $ is compatible with taking homology, we have

$$\begin{align*}\mathrm{H}_{0}(\phi(X)) \simeq E_{*}X \simeq E_{*} \otimes_{E(n)_{*}} E(n)_{*}X \end{align*}$$

as comodules. By Remark 9.8, we have an Adams spectral sequence

$$\begin{align*}\operatorname{\mathrm{Ext}}^{s, t}(E_{*}X, E_{*}X) \implies [\phi(X), P(E_{*}) \otimes_{E_{*}} E_{*}X]^{t-s}. \end{align*}$$

Using the equivalence of categories of comodules, we can rewrite the $E_{2}$ -page as

$$\begin{align*}\operatorname{\mathrm{Ext}}^{s, t}(E(n)_{*}X, E(n)_{*}X) \simeq \operatorname{\mathrm{Ext}}^{s, t}(E_{*}X, E_{*}X). \end{align*}$$

This vanishes above $n^{2}+n$ by [Reference PstragowskiPst18, Remark 2.5] and is concentrated in degrees t divisible by $2p-2$ . Since $2p-2> n^{2}+n$ by assumption, we deduce that the spectral sequence collapses on the second page, so that the identity of $E_{*}X$ descends to an equivalence $\phi (X) \simeq P(E_{*}) \otimes _{E_{*}} E_{*}X$ .

This establishes the result for $X = S^{0}_{E}$ , which has $E(n)_{*}X$ homology concentrated in degrees divisible by $2p-2$ . If K is a Morava K-theory, then as a consequence of the nilpotence theorem, it is a module over the minimal Morava K-theory $K(n)$ of Section 3 and so equivalent as a spectrum to a direct sum of $K(n)$ s. As $\phi $ preserves direct sums and

$$\begin{align*}E(n)_{*}K(n) \simeq K(n)_{*} \otimes_{E(n)_{*}} E(n)_{*}E(n) \end{align*}$$

is concentrated in degrees divisible by $2p-2$ , the result follows also for $X = K$ .

Remark 9.11. The detour into Johnson-Wilson homology Lemma 9.10 can be avoided, by directly defining a splitting of order $(2p-2)$ on the category $\operatorname {\mathrm {Comod}}_{E_{*}E}$ by using the equivalence with quasicoherent sheaves on the moduli of formal groups of height at most n. We decided against it, as the degree divisibility argument involving $E(n)$ is classical and well-known.

Let us write

for the algebraic model for the Morava K-theory spectrum. Note that its homotopy groups satisfy

so that $K_{alg}$ is a field object in $P(E_{*})$ . Consequently, for a map $M \rightarrow N$ of $P(E_{*})$ -modules, the following two conditions are equivalent:

  1. (1) $K_{alg} \otimes _{P(E_{*})} M \rightarrow K_{alg} \otimes _{P(E_{*})} N$ is a split monomorphism of $P(E_{*})$ -modules or

  2. (2) $[N, K_{alg}]_{*} \rightarrow [M, K_{alg}]_{*}$ is an epimorphism of graded abelian groups.

This forms a class of monomorphisms and so determines an Adams spectral sequence [Reference Patchkoria and PstragowskiPP21, Section 3.1].

Definition 9.12. We call the Adams spectral sequence in $P(E_{*})$ -modules determined by the above class of monomorphisms the $K_{alg}$ -based Adams spectral sequence.

We are now ready to verify the correspondence between the topological and algebraic Adams spectral sequences; we learned the following elegant argument from Robert Burklund.

Proposition 9.13. If $2p-2> n^{2}+n+1$ , then the K-based Adams spectral sequence in for $S^{0}_{E}$ is isomorphic to the $K_{alg}$ -based Adams spectral sequence for $P(E_{*})$ in $P(E_{*})$ -modules.

Proof. We claim that the equivalence $\phi $ of Theorem 9.6 induces an isomorphism of exact couples leading to these spectral sequences. Both of these are obtained by mapping into suitable towers, so we have to verify that $\phi $ takes a K-Adams resolution of $S^{0}_{E}$ to a $K_{alg}$ -Adams resolution of $\phi (S^{0}_{E}) \simeq P(E_{*})$ . If $2p-2> n^{2}+n+1$ , the equivalence $\phi $ is compatible with triangulated structures [Reference PstragowskiPst21 , Corollary B.8], so it remains to show that it identifies K-injectives with $K_{alg}$ -injectives, as the corresponding class of monomorphism is then uniquely determined. This follows immediately from Lemma 9.10, as on both sides each injective is a direct sum of shifts of, respectively, K and $K_{alg}$ .

In our case, in Proposition 9.13, we considered a $K_{alg} = P(E_{*}) \otimes E_{*}K$ -based Adams spectral sequence for the monoidal unit $P(E_{*})$ . Both objects arise through periodicisation, giving us additional information, which we now make explicit.

Proposition 9.14. If $2p-2> n^{2}+n+1$ , then the K-based Adams spectral sequence for $S^{0}_{E}$ can be given an additional grading, so that it becomes isomorphic to the $E_{*}K$ -based Adams spectral sequence in .

Proof. By Proposition 9.13, the K-Adams spectral sequence in is isomorphic to the $K_{alg}$ -based Adams spectral sequence in $P(E_{*})$ -modules. The latter is isomorphic to the spectral sequence induced by the Amitsur resolution

$$\begin{align*}P(E_{*}) \rightarrow K_{alg} \rightrightarrows K_{alg} \otimes_{P(E_{*})} K_{alg} \Rrightarrow \ldots \end{align*}$$

which is an image of the $E_{*}K$ -Adams resolution of $E_{*}$ in under the periodicisation functor. The statement follows from the isomorphism of homotopy groups of Remark 9.9 applied to the exact couple giving rise to the spectral sequence.

The above result reduces the study of the K-based Adams spectral sequence at large primes to the study of the algebraic $E_{*}K$ -based in the derived $\infty $ -category of comodules. The latter can be described explicitly in terms of the cohomology of the Morava stabiliser group, with no assumptions on the prime, which is our next step.

We will need to recall some results on décalage, following Deligne and Levine [Reference LevineLev15].

Construction 9.15. If $X^{\bullet }$ is a cosimplicial spectrum, we have an associated conditionally convergent spectral sequence

The décalage of this cosimplicial object is the tower

obtained by totalising the Postnikov truncations of X. Since limits commute with limits, we have

$$\begin{align*}\varprojlim \operatorname{\mathrm{Dec}}_{n} \simeq \varprojlim \operatorname{\mathrm{Tot}}(\tau_{\leq n} X^{\bullet}) \simeq \operatorname{\mathrm{Tot}}(\varprojlim \tau_{\leq n} X^{\bullet}) \simeq \operatorname{\mathrm{Tot}}(X^{\bullet}). \end{align*}$$

The above equivalence induces a spectral sequence associated to the tower on the left, which is conditionally convergent and of signature

Levine proves that the evident isomorphisms between the $E^{2}$ -term of the $\operatorname {\mathrm {Tot}}$ -spectral sequence and the $E_{1}$ -term of the spectral sequence associated to the décalage extends to an isomorphism of spectral sequences [Reference LevineLev15].

In our case, we will be working with cosimplicial objects in , rather than in spectra. Thus, the role of the Postnikov towers will be played by the truncations in the standard t-structure on the derived category.

Definition 9.16. Let

be a cosimplicial object in the derived $\infty $ -category of comodules. The homological décalage of $X^{\bullet }$ is the tower

where $\tau _{\leq n}$ denotes the truncation in the standard t-structure on the derived $\infty $ -category.

Warning 9.17. Note that if $X^{\bullet }$ is a cosimplicial object in , then the homological décalage tower induces a spectral sequence obtained by applying $\operatorname {\mathrm {Ext}}(E_{*}, -)$ . Since Postnikov towers converge in , this is conditionally convergent to $\operatorname {\mathrm {Ext}}(E_{*}, \operatorname {\mathrm {Tot}}(X^{\bullet }))$ .

The layers of the tower are given, up to a shift, by $\operatorname {\mathrm {Tot}}(H_{k}(X^{\bullet }))$ , so that this spectral sequence has signature

$$\begin{align*}\operatorname{\mathrm{Ext}}(E_{*}, \operatorname{\mathrm{Tot}}(H_{k}(X^{\bullet})) \implies \operatorname{\mathrm{Ext}}(E_{*}, \operatorname{\mathrm{Tot}}(X^{\bullet})). \end{align*}$$

This spectral sequence is usually not the same as the one obtained by applying $\operatorname {\mathrm {Ext}}(E_{*}, -)$ to $X^{\bullet }$ itself, because the homological t-structure does not interact in an easy way with $E_{*}$ -homotopy groups, unlike in the case of the standard t-structure on the $\infty $ -category of spectra.

Despite the above warning, for a certain restricted class of cosimplicial objects, we do have an isomorphism between the spectral sequence of a cosimplicial object and its homological décalage.

Lemma 9.18. Let be a cosimplicial object, and assume that each $X^{m}$ is a direct sum of shifts of objects in the heart, each of which is a cofree $E_{*}E$ -comodule. Then

$$\begin{align*}F(E_{*}[t], h\operatorname{\mathrm{Dec}}_{n} X^{\bullet}) \simeq \operatorname{\mathrm{Dec}}_{n} F(E_{*}, X^{\bullet}), \end{align*}$$

where $F(E_{*}[t], -)$ is the internal mapping spectrum in . That is, for such cosimplicial objects, mapping out of $E_{*}[t]$ takes homological décalage to the spectral one.

Proof. Since $F(E_{*}, -)$ preserves totalisations, it is enough to check that $F(E_{*}, -)$ takes homological truncations to Postnikov truncations. Since $X^{\bullet }$ is levelwise a direct sum of shifts of cofree comodules, it is enough to check this in the latter case, where it is clear since $\operatorname {\mathrm {Ext}}^{s}(E_{*}[t], C) = 0$ for $s> 0$ whenever C is cofree.

Corollary 9.19. The $E_{*}K$ -based Adams spectral sequence in has a second page isomorphic to the first page of the spectral sequence associated to the homological décalage $h\operatorname {\mathrm {Dec}}_{n} (E_{*}K)^{\otimes \bullet }$ of the Amitsur resolution.

Proof. Both the Adams spectral sequence and the spectral sequence of the tower are obtained by applying $F(E_{*}[t], -)$ (for all t at once) and using the relevant spectral sequence in spectra. Thus, the result then follows from Levine’s work and Lemma 9.18, since

$$\begin{align*}E_{*}K^{\otimes n} \simeq (E_{*}E)^{\otimes n} \otimes_{E_{*}} K_{*} ^{\otimes_{E_*} n} \end{align*}$$

and

$$\begin{align*}K_{*}^{\otimes_{E_*} n} \simeq \operatorname{\mathrm{Tor}}^{E_{*}}(K_{*}, K_{*}) \otimes_{K_{*}} \ldots \otimes_{K_{*}} \operatorname{\mathrm{Tor}}^{E_{*}}(K_{*}, K_{*}), \end{align*}$$

where the right-hand side has $(n-1)$ factors and the unadorned tensor products are the derived tensor products over $E_{*}$ . This is a direct sum of shifts of $K_{*}$ , as needed.

The idea is now to relate the homological décalage of $E_{*}K$ to that of $K_{*}$ .

Lemma 9.20. The morphism $K_{*} \rightarrow E_{*}E \otimes K_{*} \simeq E_{*}K$ of algebras in the derived category of $E_*E$ -comodules induces an isomorphism of spectral sequences associated to the homological décalage of Amitsur resolutions.

Proof. Since $E_{*}E$ is flat, for any , we have $\mathrm {H}_{n}(E_{*}E \otimes X) \simeq E_{*}E \otimes \mathrm {H}_{n}(X)$ . Thus, the map between the layers of the homological décalage towers is given by applying totalisation to the map

$$\begin{align*}\mathrm{H}_{n}(K_{*}^{\otimes \bullet}) \rightarrow E_{*}E^{\otimes \bullet} \otimes \mathrm{H}_{n}(K_{*}^{\otimes \bullet}). \end{align*}$$

The map is obtained by tensoring the map

$$\begin{align*}E_{*}^{\otimes \bullet} \rightarrow E_{*}E^{\otimes \bullet}, \end{align*}$$

which is a quasi-isomorphism of levelwise flat cosimplicial comodules, with $\mathrm {H}_{n}(K_{*}^{\otimes \bullet })$ , so it is a quasi-isomorphism again. It follows that it is an equivalence after taking totalisations.

Proposition 9.21. From the second page on, the Adams spectral sequence associated to $E_{*}K$ is isomorphic to the spectral sequence obtained from the tower

$$\begin{align*}\ldots \rightarrow E_{*} / \mathfrak{m}^{2} \rightarrow E_{*} / \mathfrak{m}, \end{align*}$$

that is, it is the filtration by powers spectral sequence.

Proof. We know from Corollary 9.19 that this Adams spectral sequence has second page isomorphic to the spectral sequence of the homological décalage tower, which is in turn equivalent to the homological décalage tower associated to the $K_{*}$ -Adams resolution by Lemma 9.20. Thus, it is enough to identify the latter.

We’re interested in the cosimplicial object

$$\begin{align*}K_{*} \rightrightarrows K_{*} \otimes _{E_{*}} K_{*} \Rrightarrow \ldots, \end{align*}$$

all tensor products being implicitly derived. Everything here is $2$ -periodic and concentrated in even degrees in the internal grading, so that we can instead focus on the cosimplicial object

$$\begin{align*}K_{0} \rightrightarrows K_{0} \otimes_{E_0} K_{0} \Rrightarrow \ldots, \end{align*}$$

working in the derived category of $E_{0}$ -modules. As an object of the latter, $K_{0} \otimes _{E_0} K_{0}$ is a direct sum of its homology groups, and we have

$$\begin{align*}H_{*}(K_{0} \otimes_{E_{0}} K_{0}) \simeq \operatorname{\mathrm{Tor}}^{E_{0}}_{*}(K_{0}, K_{0}) \end{align*}$$

and more generally

(9.22) $$ \begin{align} H_{*}(K_{0}^{\otimes_{E_0} n}) \simeq \operatorname{\mathrm{Tor}}_{*}^{E_{0}}(K_{0}, K_{0})^{\otimes_{K_{0}} n-1}, \end{align} $$

where on the left we have the derived tensor product of $E_{0}$ -modules and on the right the ordinary tensor product of graded $K_{0}$ -modules.

Using that $E_{0}$ is a regular ring with residue field $K_{0}$ , the canonical isomorphism

$$\begin{align*}\operatorname{\mathrm{Tor}}_{1}^{E_{0}}(K_{0}, K_{0}) \simeq (\mathfrak{m} / \mathfrak{m}^{2})^{\vee} \end{align*}$$

with the tangent space extends to a grading-preserving isomorphism

$$\begin{align*}\operatorname{\mathrm{Tor}}_{*}^{E_{0}}(K_{0}, K_{0}) \simeq \Lambda_{K_{0}}((\mathfrak{m} / \mathfrak{m}^{2})^{\vee}) \end{align*}$$

with the exterior algebra. This is flat over $K_{0}$ , which is a field, so by standard arguments, the cosimplicial object $K_{0}^{\otimes \bullet }$ on the right of (9.22) encodes the cobar complex computing

$$\begin{align*}\text{Cotor}_{\Lambda_{K_{0}}((\mathfrak{m} / \mathfrak{m}^{2})^{\vee})}(K_{0}, K_{0}) \simeq \operatorname{\mathrm{Sym}}_{K_{0}}(\mathfrak{m}/\mathfrak{m}^{2}) \simeq \bigoplus_{n \geq 0} \mathfrak{m}^{n}/\mathfrak{m}^{n+1}. \end{align*}$$

Note that this is bigraded using the internal grading of the exterior algebra and the $\text {Cotor}$ -grading, with the summand $\mathfrak {m}^{n} / \mathfrak {m}^{n+1}$ being concentrated in degrees $(n, n)$ .

Using the isomorphism in Equation (9.22) and passing to cohomology, we deduce that

$$\begin{align*}H^{s}(H_{n}(K_{0}^{\otimes_{E_{0}} \bullet})) \simeq \begin{cases} \mathfrak{m}^{n}/\mathfrak{m}^{n+1} & \mbox{when } s=n,\\ 0 & \mbox{otherwise,} \end{cases} \end{align*}$$

where $H^{s}$ is the cohomology of the given cosimplicial abelian group. Thus, the totalisation spectral sequence for $H_{n}(K_{0}^{\otimes _{E_{0}} \bullet })$ , which we consider as a cosimplicial object of the heart of the derived $\infty $ -category of $E_{0}$ -modules, collapses, and we deduce that

$$\begin{align*}\operatorname{\mathrm{Tot}}(H_{n}(K_{0}^{\otimes \bullet})) \simeq \Sigma^{-n} \mathfrak{m}^{n} / \mathfrak{m}^{n+1}, \end{align*}$$

It follows that the graded pieces of the homological décalage filtration of $E_{*}$ are given by

$$\begin{align*}\mathrm{fib}(\operatorname{\mathrm{Dec}}_{n} \rightarrow \operatorname{\mathrm{Dec}}_{n-1}) \simeq \operatorname{\mathrm{Tot}}(\Sigma^{n} H_{n}(K_{*}^{\otimes \bullet})) \simeq \mathfrak{m}^{n} / \mathfrak{m}^{n+1} \otimes_{E_{0}} E_{*}, \end{align*}$$

and so by induction, the tower itself must be of the claimed form.

Theorem 9.23. If $2p-2> n^{2}+n+1$ , the K-based Adams spectral sequence can be given an additional grading so that it becomes isomorphic to the spectral sequence induced by applying $\operatorname {\mathrm {Ext}}_{E_{*}E}(E_{*}, -)$ to the filtration of $E_{*}$ given by powers $\mathfrak {m}^{n} E_{*}$ of the maximal ideal.

Proof. This is a combination of Propositions 9.14 and 9.21.

We believe the following question related to the above result is interesting, but we do not pursue it in this paper.

Definition 9.24. The additional grading guaranteed by Theorem 9.23 should provide certain restrictions on the possible differentials in the K-based Adams spectral sequence at large primes. Can one find out explicitly what are these restrictions?

Remark 9.25. If we pick $E = E_{n}$ to be the Morava E-theory of the Honda formal group law over $\mathbb {F}_{p^{n}}$ , then since $\mathfrak {m}^{n} / \mathfrak {m}^{n+1} E_{*}$ is $\mathfrak {m}$ -torsion, we have

$$\begin{align*}\operatorname{\mathrm{Ext}}_{E_{*}E}^*(E_{*}, \mathfrak{m}^{n} / \mathfrak{m}^{n+1} E_{*}) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{*}(\mathbb{G}_{n}, \mathfrak{m}^{n} / \mathfrak{m}^{n+1} E_{*}). \end{align*}$$

Thus, the spectral sequence of Theorem 9.23 is isomorphic to the conditionally convergent spectral sequence

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^{*}(\mathbb{G}_{n}, \mathfrak{m}^{n}/\mathfrak{m}^{n+1} E_{*}) \implies \mathrm{H}_{\operatorname{\mathrm{cts}}}^{*}(\mathbb{G}_{n}, E_{*}) \end{align*}$$

obtained by the same filtration of $E_{*}$ but in continuous $\mathbb {G}_{n}$ -modules.

10 Height 1 K-based Adams spectral sequence at an odd prime

Let us describe how, using our methods, one obtains an explicit description of the K-based Adams spectral sequence at $n=1$ and p odd. Since in this case

$$\begin{align*}2p-2 \geq 4> 3 = n^{2}+n+1. \end{align*}$$

Theorem 9.23 and Remark 9.25 imply that the relevant spectral sequence is isomorphic to the one computing the cohomology $\mathrm {H}_{\operatorname {\mathrm {cts}}}^{*}(\mathbb {G}_{n}, E_{*})$ using the filtration by powers of the maximal ideal, where $E_{0}$ is the Lubin–Tate ring of the Honda formal group law.

Notation 10.1. We again follow the conventions of [Reference Goerss, Henn, Mahowald and RezkGHMR05, Section 2]. We have $E_{*} \simeq \mathbb {Z}_{p}[u^{\pm 1}]$ with $|u| = -2$ , $\mathfrak {m} = (p)$ and $\mathbb {G}_{1} \simeq \mathbb {Z}_{p}^{\times }$ with the action determined by $\lambda _{*}(u) = \lambda ^{-1} u$ for $\lambda \in \mathbb {Z}_{p}^{\times }$ . We denote the associated graded of $E_{*}$ by

$$\begin{align*}A_{*} \simeq \mathbb{F}_{p}[b][u^{\pm1}], \end{align*}$$

with $|b| = (0, 1)$ the equivalence class of $p \in E_{0}$ , and $|u| = (-2, 0)$ , where the first degree is internal, and the second one is coming from the filtration.

The p-adic group $\mathbb {Z}_{p}^{\times }$ is topologically cyclic at odd primes, generated by $\psi = \sigma (1 + p)$ for $\sigma $ a primitive $(p-1)$ -th root of unity. It follows that for a profinite $\mathbb {Z}_{p}^{\times }$ -module M, its cohomology can be computed using the $2$ -term complex

(10.2) $$ \begin{align} \partial\colon M \rightarrow M, \end{align} $$

where $\partial = id_{M} - \psi _{*}$ .

The complex of (10.2) is a quasiisomorphic quotient of the standard group cohomology cochain complex

(10.3) $$ \begin{align} M \rightarrow \operatorname{\mathrm{Map}}_{\operatorname{\mathrm{cts}}}(\mathbb{Z}_{p}^{\times}, M) \rightarrow \operatorname{\mathrm{Map}}_{\operatorname{\mathrm{cts}}}(\mathbb{Z}^{\times}_{p} \times \mathbb{Z}_{p}^{\times}, M) \rightarrow \ldots, \end{align} $$

the quotient map being given by the identity in degree zero and evaluation at the generator $\psi \in \mathbb {Z}_{p}^{\times }$ in degree one.

From this explicit description, we see that if we equip M with a filtration, the above quotient map is a quasi-isomorphism of filtred complexes, where we consider both (10.2) and (10.3) with the filtration induced from that of M. In particular, both filtrations induced isomorphic spectral sequences.

Remark 10.4. The 2-term complex of (10.2) can be used to directly compute the cohomology groups $\mathrm {H}_{\operatorname {\mathrm {cts}}}^{*}(\mathbb {Z}_{p}^{\times }, \mathbb {Z}_{p}[u^{\pm 1}])$ , recovering the classical image of J pattern [Reference LurieLur10, Lecture 35]. Our goal is not to compute the above groups, which are well-known, but rather analyse the structure of the spectral sequence associated to filtration by powers of p.

We first determine the cohomology groups of the associated graded $A_*$ . We have $\psi _{*} b = b$ , because the latter can be represented by $p \in E_{0}$ which is necessarily acted on trivially, and since $\psi _{*} u \equiv \sigma ^{-1} u \pmod p$ , we have $\psi _{*} u = [\sigma ]^{-1} u$ in the associated graded, where $[\sigma ] \in \mathbb {F}_{p}$ is the image of $\sigma $ . Thus, in the associated graded, we have that $\partial (b) = 0$ and $\partial (u^{k})$ is a unit multiple of $u^{k}$ for $(p-1) \nmid k$ and zero otherwise. We deduce the following.

Proposition 10.5. The $E_{2}$ -term of the K-based Adams for $S^{0}$ at $n=1$ and $p> 2$ is given by

$$\begin{align*}\operatorname{\mathrm{Ext}}_{K_{*}K}^*(K_{*}, K_{*}) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{*}(\mathbb{G}_{1}, A_{*}) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{*}(\mathbb{Z}_{p}^{\times}, \mathbb{F}_{p}[b][u^{\pm 1}]) \simeq \mathbb{F}_{p}[b][v_{1}^{\pm 1}] \otimes \Lambda(\zeta), \end{align*}$$

where $v_{1} = u^{1-p}$ is of degree $(2p-2, 0, 0)$ and $\zeta $ is the class of $1$ of degree $(0, 0, 1)$ , where the three degrees are, respectively, the internal degree, the degree of the associated graded and the cohomological degree.

By Remark 9.25, if the K-based Adams is isomorphic to the spectral sequence computing $\mathrm {H}_{\operatorname {\mathrm {cts}}}^{*}(\mathbb {Z}_{p}^{\times }, \mathbb {Z}_{p}[u^{\pm 1}])$ induced by the filtration of (10.2) by powers of p, with $E_{2}$ -term as above and with differentials $d_{r}\colon E_{r} \rightarrow E_{r}$ of degree $(0, r, 1)$ . We now analyse this spectral sequence.

We know that $\partial (p) = 0$ in $E_{0}$ , so that b is a permanent cycle. The same is true for $\zeta $ , for degree reasons, and we deduce that all of the differentials are both b and $\zeta $ -linear, and so the structure of the spectral sequence is completely determined by what it does on $v_{1}^{k}$ . If we write $k = p^{n}m$ , where $p \nmid m$ , then one can calculate

$$\begin{align*}\partial(u^{(1-p)k}) \equiv \text{unit} \cdot p^{n+1} u^{(1-p)k} \pmod {p^{n+2}} \end{align*}$$

from which we deduce that

(10.6) $$ \begin{align} d_{i}(v_{1}^{k}) = \begin{cases} 0 & \text{for } i < n+1 \\ \zeta b^{n+1} v_{1}^{k} & \text{for } i = {n+1}. \end{cases} \end{align} $$

Note that the first computation is also implied by the Leibniz rule for p-th powers. The extension problems are resolved using multiplication by b, recovering the classical answer that

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^{s, t}(\mathbb{Z}_{p}^{\times}, \mathbb{Z}_{p}[u^{\pm 1}]) = \begin{cases} \mathbb{Z}_{p} & \mbox{if } (s, t) = (0, 0), \\ \mathbb{Z}_{p} \{\zeta\} & \mbox{if } (s, t) = (1, 0), \\ \mathbb{Z}/p^{n+1} \{\zeta u^{(p-1)p^{n}m} \} & \mbox{if } (s, t) = (1, (2p-2)p^{n}m) \mbox{, where } p \nmid m, \\ 0 & \mbox{otherwise,} \end{cases} \end{align*}$$

where $\{-\}$ denotes a generator of the given group. Thus, the spectral sequence is as in the following familiar ‘image of J’ pattern

with even longer differentials supported on $v_{1}^{p^{k}}$ for $k \geq 1$ . The above picture is made in the Adams grading $(t-s, s)$ , with t the internal degree and s the cohomological one, while the one inherited from passing to the associated graded not visible.

It is interesting to observe that this shows that already at height one, the K-based Adams spectral sequence has nonzero differentials of arbitrary length.

Example 10.7 (Noncompletely convergent K-Adams).

Using the above calculation, we can give an example of a K-local spectrum for which its K-based Adams spectral sequence is not completely convergent. Note that we know that it is always conditionally convergent by Proposition 7.2.

To this end, we construct a spectrum X for which $\operatorname {\mathrm {lim}}_r^1E_r^{0,0}(X)$ does not vanish at height $n =1$ and $p> 2$ . Set $\lambda _k = 2(p-1)p^k$ , and consider the spectrum

$$\begin{align*}X = L_{K}\bigoplus_{k\ge 0}S^{-\lambda_k}. \end{align*}$$

In bidegree $(s,t) = (0,0)$ , the $E_2$ -page is given by

$$\begin{align*}E_2^{0,0}(X) \simeq \bigoplus_{k\ge 0} \mathbb{F}_p\{v_1^{p^k}\}, \end{align*}$$

where the generators correspond to the maps $v_1^{p^k}\colon K_* \to K_*S^{\lambda _k}$ . The formulas for the differentials of Equation (10.6) show that (up to reindexing) the filtration on $E_2^{0,0}(X)$ is given by

$$\begin{align*}\ldots \subset \bigoplus_{k \ge 2}\mathbb{F}_p\{v_1^{p^k}\} \subset \bigoplus_{k \ge 1}\mathbb{F}_p\{v_1^{p^k}\} \subset \bigoplus_{k \ge 0}\mathbb{F}_p\{v_1^{p^k}\} = E_2^{0,0}(X). \end{align*}$$

Therefore, we obtain an exact sequence

$$\begin{align*}0 \to \operatorname{\mathrm{lim}}_rE_r^{s,t}(X) \to E_2^{0,0}(X) = \bigoplus_{k\ge 0} \mathbb{F}_p\{v_1^{p^k}\} \to \prod_{k \ge 0}\mathbb{F}_p\{v_1^{p^k}\} \to \operatorname{\mathrm{lim}}_r^1E_r^{s,t}(X) \to 0. \end{align*}$$

In particular, we see that $\operatorname {\mathrm {lim}}_rE_r^{s,t}(X) = 0$ , while $\operatorname {\mathrm {lim}}_r^1E_r^{s,t}(X) \neq 0$ .

Part 3. Homology of inverse limits and the algebraic chromatic splitting conjecture

In the third part of the work, we largely move away from Morava K-theory, and we focus on homology of K-local spectra. From the perspective of E-local category, K-localisation is a form of completion, and so we first focus on homology of inverse limits, constructing a spectral sequence computing these in the generality of an arbitrary adapted homology theory.

In the case of K-localisation, the $E_{2}$ -page of this spectral sequence is given by derived functors of limits in $E_{*}E$ -comodules. We describe the latter in terms of cohomology of the Morava stabiliser group, and use it to compute the zeroth one at all heights and primes. At height 1, we compute these derived functors completely.

11 The homology of inverse limits

We begin with a general review of the context for the construction of the modified Adams spectral sequence, following the approach of Devinatz and Hopkins [Reference DevinatzDev97]. This approach will then be employed to construct a spectral sequence that computes the homology of inverse limits in a presentable stable $\infty $ -category.

In particular, this gives rise to a spectral sequence for computing the E-homology of the inverse limit of a tower of spectra $(X_{\alpha })$ from the derived functors of inverse limits of the tower of $E_*E$ -comodules $(E_*X_{\alpha })$ , for suitable ring spectra E. The question of when this spectral sequence converges is subtle, and will be studied in detail in the case of Morava E-theory. The material in this section is based on unpublished work of Mike Hopkins and Hal Sadofsky.

11.1 Adapted homology theories

In this short section, we recall basic facts about adapted homology theories. Informally, these are exactly those homology theories which admit an Adams spectral sequence based on injectives. Everything here is classical, although our presentation is most close to [Reference Patchkoria and PstragowskiPP21, Section 2].

A locally graded $\infty $ -category is an $\infty $ -category equipped with a distinguished autoequivalence . A locally graded functor is functor equipped with a natural isomorphism .

Definition 11.1. Let be a stable $\infty $ -category, considered as a locally graded $\infty $ -category using the suspension functor, and an arbitrary locally graded abelian category. We say a locally graded functor is a homology theory if, for any cofibre sequence

$$\begin{align*}X \rightarrow Y \rightarrow Z \end{align*}$$

in , the induced diagram

$$\begin{align*}H(X) \rightarrow H(Y) \rightarrow H(Z) \end{align*}$$

in is exact in the middle.

Remark 11.2. The requirement that H is locally graded amounts to specifying an isomorphism

$$\begin{align*}H(\Sigma X) \simeq H(X)[1] \end{align*}$$

natural in .

In cases of interest to us, H is Grothendieck in the sense that

  1. (1) is presentable,

  2. (2) is Grothendieck abelian and

  3. (3) H preserves arbitrary direct sums.

In particular, this means that

has enough injectives. Any injective object I of

gives rise to a cohomological functor

Since

is presentable and stable, Brown’s representability theorem holds [Reference Patchkoria and PstragowskiPP21, Proposition 2.15], so that there exists some

representing

. It follows that, for any object

, there is a natural equivalence

Note that the object $D(I)$ is H-local, in the sense that for any object

with $H(Y) = 0$ , we have $\operatorname {\mathrm {Hom}}(Y,D(I)) =0$ . Moreover, the identity map on $D(I)$ corresponds under this isomorphism to a natural counit map $H(D(I)) \to I$ .

Definition 11.3. We say is adapted if the counit map $H(D(I)) \to I$ is an equivalence for any injective .

Example 11.4. Rational homology, viewed as a functor from spectra to graded rational vector spaces, is an adapted homology theory. In this case, the lift $D(V)$ of a (graded) $\mathbb {Q}$ -vector space V is the (generalised) Eilenberg–MacLane spectrum $HV$ .

Example 11.5. In contrast to the previous example, mod p homology is not adapted for any p; indeed, the lift of $\mathbb {F}_p$ is $H\mathbb {F}_p$ , but its mod p-cohomology is the mod p Steenrod algebra ${\mathcal {A}}_p$ which is larger than $\mathbb {F}_p$ .

However, $H_*(-,\mathbb {F}_p)$ has more structure: it takes values in the category $\operatorname {\mathrm {Comod}}_{{\mathcal {A}}_p}$ of graded ${\mathcal {A}}_p$ -comodules. It turns out that the homology theory

$$\begin{align*}H_*(-;\mathbb{F}_p)\colon \operatorname{\mathrm{Sp}} \to \operatorname{\mathrm{Comod}}_{{\mathcal{A}}_p} \end{align*}$$

is adapted.

Remark 11.6. The phenomena visible in Example 11.5 is typical in the sense that asking for H to be adapted is to ask for to encode all available homological information. This generalises considerably: one can show that any homology theory factors uniquely through an adapted one followed by an exact comonadic functor of abelian categories [Reference Patchkoria and PstragowskiPP21, Section 3.3]

Let R be a homotopy commutative ring spectrum which satisfies the Adams condition, that is, it can be written as a filtred colimit of finite spectra $X_{\alpha }$ with the properties that

  1. (1) $R_*X_{\alpha }$ is a finitely generated projective $R_*$ -module and

  2. (2) the Künneth map $R^{*}X_{\alpha } \rightarrow \operatorname {\mathrm {Hom}}_{R_{*}}(R_{*}X_{\alpha }, R_{*})$ is an isomorphism.

Note that the second condition follows from the first, whenever R can be made $\mathbf {E}_{1}$ .

For example, $H \mathbb {F}_{p}$ or any Landweber exact homology theory satisfy the Adams condition [Reference HoveyHov04a, Theorems 1.4.7–1.4.9], but $H\mathbb {Z}$ does not [Reference Goerss and HopkinsGH, Page 17]. This condition guarantees that the associated Hopf algebroid $(R_*,R_*R)$ is Adams and thus has a well-behaved category of comodules $\operatorname {\mathrm {Comod}}_{R_*R}$ (see [Reference HoveyHov04a, Section 1.4] for details).

One way in which the Adams-type condition implies that the category $\operatorname {\mathrm {Comod}}_{R_{*}R}$ is well-behaved also in the topological sense is the following result of Devinatz.

Lemma 11.7 [Reference DevinatzDev97, Theorem 1.5 and Section 2].

Let R be a topologically flat commutative ring spectrum. For any injective $R_*R$ -comodule I, the identity map on $D(I)$ corresponds (in the sense explained above) to an isomorphism $R_*D(I) \simeq I$ . In other words, the functor

is an adapted homology theory.

11.2 Construction of the spectral sequence

The starting point of our construction is the existence of modified Adams towers for any homology theory . We collect its properties in the next result:

Lemma 11.8. Consider an adapted homology theory

. Let

, and suppose

is an injective resolution of $H(X)$ in

, where $C_i = \ker (\tau _i)$ for all i. There exists a tower of objects in

over X of the form

where the dotted maps are the boundary maps shifting degree by $1$ , and such that the following properties are satisfied for all i:

  1. (1) $X_{i+1} \simeq \operatorname {\mathrm {fib}}(f_i)$ ;

  2. (2) $H(X_i) \simeq C_i[{-i}]$ ;

  3. (3) $H(f_i) = \eta _i[{-i}]$ ;

  4. (4) $H(g_i)=0$ ;

  5. (5) $H(\delta _i)$ is the surjection $I_i[{-i}] \to C_{i+1}[{-i}]$ .

If X is H-local, then $X_i$ and $D(I_i)$ are H-local for all i. Moreover, this tower is weakly functorial; that is, a map $X \to Y$ can be extended to a (noncanonical) map of towers $(X_i) \to (Y_i)$ .

Proof. This lemma is an axiomatisation of the results proven in [Reference DevinatzDev97, Section 1]. The tower so constructed consists of H-local spectra as noticed in Section 11.1, while naturality follows from the naturality of injective resolutions.

Notation 11.9. We refer to the tower $(X_i)$ constructed in Lemma 11.8 as the modified Adams tower of X with respect to the adapted homology theory .

Since the limit $\varprojlim I_{\alpha }$ of an injective tower of injectives in is injective, the construction of the previous subsection yields an object $D(\varprojlim I_{\alpha })$ of . In order to proceed, we need an auxiliary characterisation of injective towers of objects in a Grothendieck abelian category  .

Lemma 11.10. Let be a Grothendieck abelian category. An object is injective if and only if $I_{\alpha }$ is injective for all $\alpha \in J$ and all structure maps in I are split epimorphisms.

Proof. This is proven in [Reference JannsenJan88, Proposition 1.1]. We sketch the argument of the implication we need. Let $j\colon \mathbb {N}^{\delta } \to \mathbb {N}$ be the inclusion of the discrete set of natural numbers into the poset of natural numbers. This induces an adjunction $(j^*,j_*)$ between diagram categories. If I is injective, then the natural monomorphism $I \to j_*j^*I$ is split. By construction, the structure maps of $j_*j^*I$ are projections, so I also has split surjective structure maps, and the claim follows.

Proposition 11.11. If $I=(I_{\alpha }) \in \operatorname {\mathrm {Inj}}({\mathcal {A}}^{\mathbb {N}})$ is an injective tower in

, then there is a preferred equivalence

of objects in

, well-defined up to homotopy.

Proof. For brevity, let us write

; note that this is an injective object of

. The canonical structure maps

give arrows

$$\begin{align*}D(I_{\infty}) \rightarrow D(I_{\alpha}), \end{align*}$$

well-defined and compatible up to homotopy. By the Milnor exact sequence, these can be lifted to a homotopy class of maps

in

. We claim this is an equivalence, which we will check by verifying that both sides represent the same functor in the homotopy category.

Indeed, for any

, there are isomorphisms

The Milnor sequence associated to the limit $\varprojlim D(I_{n})$ takes the form

(11.12)

It follows from Lemma 11.10 that the structure maps in the tower

are split epimorphisms, so the $\varprojlim ^1$ -term in (11.12) vanishes. Thus, the Yoneda lemma implies that $\phi $ is an equivalence, as claimed.

The spectral sequence we construct involves derived functors of the limit, and so we first establish a consistent notation for these.

Notation 11.13. If

is a Grothendieck abelian category and

is a diagram, then we write

for the limit taken in

itself. Formation of limits defines a functor

and we denote its right derived functors by

Alternatively,

has an associated derived $\infty $ -category, and we write

for the limit of the composite of F with the inclusion with the heart. These two different notions of limits, one in

and the other in the derived $\infty $ -category, are related by the formula

where on the right-hand side, we have the homology of an object of the derived $\infty $ -category. Thus,

can be thought of as the total derived functor of the limit.

Theorem 11.14. Let be an adapted homology theory. If is a tower in , then there exists a natural spectral sequence in of the form

(11.15)

with differentials $d_r^{s,t}\colon E_r^{s,t} \to E_r^{s+r,t+r-1}$ .

Proof. If H is adapted, then so is the induced homology theory

between the $\infty $ -categories of towers [Reference Patchkoria and PstragowskiPP21, Example 8.24]. Thus, we have Adams resolutions of towers, and we let $(X_i^{\alpha })_{i \geq 0}$ be a modified Adams tower of $(X^{\alpha })$ as in Lemma 11.8.

Taking limits in the Adams resolution of $X^{\alpha }$ yields a tower in

of the form

For brevity, let us write

for the internal degree shift. Setting $D_1^{s,t} = H(\varprojlim X_{s}^{\alpha })[s-t]$ and $E_1^{s,t}=H(\varprojlim \Sigma ^{-s}D(I_s^{\alpha }))[s-t]$ , this induces an exact couple of bigraded objects in

of the form

where the maps have bidegree $|i_1|=(-1,-1)$ , $|j_1|=(0,0)$ and $|k_1|=(1,0)$ . The $E_1$ -term can be identified using Proposition 11.11 and Lemma 11.7 as

and

. This gives the $E_2$ -term

as needed. It is clear from this construction and Lemma 11.8 that the resulting spectral sequence is natural in the tower $X^{\alpha }$ and that all pages and differentials are in

.

Warning 11.16. Note that since the local grading

is an equivalence, it commutes with derived functors of the limit, and in the spectral sequence of Theorem 11.14, we have

Thus, the $t = 0$ line in the spectral sequence already determines the whole $E_{2}$ -page. This is similar to the case of the Bockstein spectral sequence, which also has a periodic $E_{2}$ -page.

Remark 11.17. Suppose that $(X^{\alpha })$ is a tower under X. Then, the image

consists of permanent cycles; that is, it is in the kernel of all the differentials in the spectral sequence of Theorem 11.14.

To see this, note that the assumption gives a map from the constant tower on X to $(X^{\alpha })$ , inducing a map of spectral sequences

The $E_2$ -page of the top spectral sequence is concentrated in

so that the spectral sequence collapses. The comparison map is readily identified with the induced morphism

, so the claim follows.

11.3 Derived limits of comodules

We now specialise the above to the case of a homology theory on spectra corresponding to a ring spectrum of Adams type. In order to study the $E_2$ -term of the spectral sequence of Theorem 11.14, we begin with a general discussion of inverse limits of comodules over suitable flat Hopf algebroids. Let $(A, \Psi )$ be an Adams Hopf algebroid in the sense of [Reference HoveyHov04a][Definition 1.4.3], so that $\Psi $ is a filtred colimit of dualisable comodules. We now describe an approach to computing limits in the derived $\infty $ -category

of comodules by reducing to the case of modules. The forgetful functor $\epsilon _*\colon \operatorname {\mathrm {Comod}}_{\Psi } \to \operatorname {\mathrm {Mod}}(A)$ is left adjoint to the extended (or cofree) comodule functor $\epsilon ^*$ which sends an A-module M to $\Psi \otimes _A M$ . These functors are exact and thus give rise to an adjunction:

In terms of chain complexes, both can be computed levelwise.

The corresponding monad $\epsilon ^*\epsilon _*$ can be used to construct a resolution of any comodule. Concretely, if M is a $\Psi $ -comodule, then we have the associated cobar complex

$$\begin{align*}0 \rightarrow M \rightarrow \Psi \otimes _{A} M \rightarrow \Psi \otimes _{A} \Psi \otimes _{A} M \rightarrow \ldots, \end{align*}$$

which is a resolution of M by extended comodules, that is, those of the form $\epsilon ^{*} N = \Psi \otimes _{A} N$ for an A-module N.

One way to phrase that the cobar complex is exact is to say that the augmented cosimplicial object from which it arises, namely

(11.18) $$ \begin{align} M \rightarrow \Psi \otimes _{A} M \rightrightarrows \Psi \otimes _{A} \Psi \otimes_{A} M \Rrightarrow \ldots, \end{align} $$

is a limit diagram in the derived $\infty $ -category

. Now, since limit diagrams are stable under levelwise limits, it follows that if $(M_{i})$ is a diagram of comodules, then the diagram

is also a limit, giving an approach to computing

. To see this, notice that since $\epsilon ^{*}$ is a right adjoint and thus preserves limits, we have

Applying this to the cosimplicial diagram (11.18), we see that we get a limit diagram of the form

which expresses the limit in the derived category of comodules using only limits taken in the category of modules. Passing to homology, which encodes the derived functors of the limit in the categories of A-modules and $\Psi $ -comodules, we deduce the following.

Proposition 11.19. If $M_{i}$ is a diagram of comodules, then there exists a spectral sequence of comodules of signature

computing the derived functors of the limit in comodules.

Remark 11.20. Note that in the particular case of sequential inverse limits, that is, diagrams of the form

$$\begin{align*}\ldots \rightarrow M_{2} \rightarrow M_{1} \rightarrow M_{0}, \end{align*}$$

this spectral sequence collapses after at most two pages, since, in this case, we have $\textstyle \varprojlim ^{s} _{A} N_{i} = 0$ for $s \neq 0, -1$ and any diagram $N_{i}$ of A-modules.

Remark 11.21. In an even more specific case, let us assume that we work with sequential inverse limits and that the maps $M_{n+1} \rightarrow M_{n}$ are all epimorphisms. If that is the case, the same is true for $\Psi \otimes _{A } \ldots \otimes _{A} M_{n+1} \rightarrow \Psi \otimes _{A} \ldots \otimes _{A} M_{n}$ , and we deduce using the Mittag-Leffler condition that all of the $\textstyle \varprojlim ^{1} _{A}$ -terms vanish. In this case, the spectral sequence of Proposition 11.19 has only one potentially nonzero differential.

Phrasing it without the use of spectral sequences, we see that the diagram of comodules

$$\begin{align*}\textstyle\Psi \otimes _{A} (\varprojlim _{A} M_{i}) \rightarrow \Psi \otimes _{A} (\varprojlim _{A} \Psi \otimes _{A} M_{i}) \rightarrow \ldots, \end{align*}$$

is an explicit presentation of the derived limit as a chain complex.

Example 11.22. Suppose that R is a homotopy commutative ring spectrum of Adams-type. As is an adapted homology theory by Lemma 11.7, Theorem 11.14 specialises to give a spectral sequence

$$\begin{align*}\textstyle E_2^{s,t} \simeq \varprojlim_{R_*R}^s(R_{*+t}X^{\alpha}) \implies R_{*+s+t}(\operatorname{\mathrm{lim}}_{\alpha} X^{\alpha}) \end{align*}$$

for a tower of spectra $(X^{\alpha })$ , where the derived functors of the limit are taken in $R_{*}R$ -comodules.

This is a spectral sequence in $R_{*}R$ -comodules, so that, in particular, the $E_{2}$ -page is trigraded. Passing to internal degree zero, we obtain a more-pleasant looking bigraded spectral sequence

$$\begin{align*}\textstyle E_2^{s,t} \simeq (\varprojlim_{R_*R}^s R_{*}X^{\alpha})_{t} \implies R_{s+t}(\operatorname{\mathrm{lim}}_{\alpha} X^{\alpha}). \end{align*}$$

Note that, in general, we cannot rewrite the $E_{2}$ -page as “ $\textstyle \varprojlim ^{s}_{R_{*}R}(R_{t}X^{\alpha })$ ”, as the derived functors of the limit are computed in $R_{*}R$ -comodules, a structure which cannot be restricted to a single degree.

Warning 11.23. Even for quite reasonable R, such as $R = H\mathbb {Q}$ , convergence of the spectral sequence of Example 11.22 is a subtle problem. For example, let $(M_{p^i})$ be the tower of mod $p^i$ Moore spectra with the canonical structure maps, and suppose $R=H\mathbb {Q}$ . Since

$$\begin{align*}\operatorname{\mathrm{lim}}(\ldots \longrightarrow M_{p^2} \longrightarrow M_{p}) \simeq S_p^0, \end{align*}$$

the p-complete sphere, the abutment of the spectral sequence is nontrivial, while the $E_2$ -term is zero. We study this question in more detail in the next section in the case of Morava E-theory.

Remark 11.24. The same methods as those leading to Example 11.22 have been employed by Hovey to set up a spectral sequence computing the R-homology of a product of spectra (see [Reference HoveyHov07]). In [Reference PetersonPet20, Appendix A], a different construction of the spectral sequence of Example 11.22 is given, based on Adams resolutions rather than modified Adams resolutions.

12 The Morava E-homology of inverse limits

The goal of this section is to study the spectral sequence constructed in Theorem 11.14 in the special case of (uncompleted) Morava E-homology. In particular, we identify the $E_2$ -page for the sphere spectrum in terms of the continuous cohomology of the Morava stabliser group and exhibit conditions on the tower that ensure convergence.

We will work with a particular form of Morava E-theory, which we used previously in Section 5. For convenience of the reader, let us fix our notation for the remainder of the current work.

We fix a prime p and a height $n> 0$ , and we let $\mathbf {G}_{0}$ be the Honda formal group law over . We write E for the associated Lubin-Tate spectrum, so that we have a noncanonical isomorphism

$$\begin{align*}E_{*} \simeq W(\mathbb{F}_{p^{n}})[\![ u_{1}, \ldots, u_{n-1}]\!] [u^{\pm 1}]. \end{align*}$$

We write $\mathfrak {m} = (p,u_1,\ldots , u_{n-1})$ for the maximal ideal of $E_0$ . By Goerss-Hopkins-Miller, the spectrum E is acted on by the extended Morava stabiliser group .

Warning 12.1. We remind the reader that, unless otherwise noted, we work with uncompleted E-homology, the uncompleted homology cooperations and uncompleted $E_*E$ -comodules.

12.1 Continuous cohomology of filtred colimits

In this subsection, we prove that continuous cohomology groups of $\mathbb {G}_n$ commute with certain filtred colimits. To this end, it will be useful for us to consider the following variant on the $\mathfrak {m}$ -adic topology on an $E_{0}$ -module.

Definition 12.2. Let M be an $E_{0}$ -module. The local $\mathfrak {m}$ -adic topology on M is the linear topology in which a submodule $U \subseteq M$ is open if for every finitely generated $E_{0}$ -submodule $M^{\prime } \subseteq M$ ,

$$\begin{align*}U \cap M^{\prime} \subseteq M^{\prime} \end{align*}$$

is open in the usual $\mathfrak {m}$ -adic topology on $M^{\prime }$ ; that is, we have $\mathfrak {m}^{n} M^{\prime } \subseteq U \cap M^{\prime }$ for some n depending on $M^{\prime }$ .

Example 12.3. Suppose that M is finitely generated over $E_{0}$ . Then, the local $\mathfrak {m}$ -adic topology on M coincides with the usual $\mathfrak {m}$ -adic topology.

Example 12.4. Suppose that M is an arbitrary $E_{0}$ -module. Then, we can write ${M \simeq \varinjlim M_{\alpha }}$ as a filtred colimit of finitely generated $E_0$ -modules. The local $\mathfrak {m}$ -adic topology coincides with the colimit topology if we equip each $M_{\alpha }$ with its usual $\mathfrak {m}$ -adic topology.

The importance of the local $\mathfrak {m}$ -adic topology in our context comes down to the following observation.

Remark 12.5. Let X be a spectrum. Then, $E_{0}X$ is a continuous $\mathbb {G}_{n}$ -module with respect to its local $\mathfrak {m}$ -adic topology. To see this, observe that we can write $X \simeq \varinjlim X_{\alpha }$ as a filtred colimit of finite spectra, so that

(12.6) $$ \begin{align} E_{0}X \simeq \varinjlim E_{0} X_{\alpha}. \end{align} $$

Each of $E_{0} X_{\alpha }$ is a continuous $\mathbb {G}_{n}$ -module when considered with its $\mathfrak {m}$ -adic topology, and $E_{0}X$ becomes a topological $\mathbb {G}_{n}$ -module since it has the colimit topology with respect to (12.6).

We will be interested in the continuous cohomology of $\mathbb {G}_{n}$ with coefficients in an $E_{0}$ -module equipped with its local $\mathfrak {m}$ -adic topology. As we will see, this has an elegant description in terms of cohomologies of its finitely generated submodules. The key is the following lemma.

Lemma 12.7. Let K be a compact Hausdorff topological space and M be an $E_{0}$ -module equipped with its local $\mathfrak {m}$ -adic topology. Then, any continuous map $f\colon K \rightarrow M$ factors through a finitely generated submodule. In other words, we have

$$\begin{align*}\operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(K, M) \simeq \varinjlim \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(K, M_{\alpha}), \end{align*}$$

where $M_{\alpha }$ is the poset of finitely generated submodules of M.

Proof. Suppose for the sake of contradiction that for every finitely generated submodule $M^{\prime }$ , there exists a $k \in K$ , such that $f(k) \not \in M^{\prime }$ . Proceeding inductively, we produce an increasing sequence

$$\begin{align*}M_{0} \subseteq M_{1} \subseteq M_{2} \subseteq \ldots \end{align*}$$

of finitely generated submodules and points $k_{n} \in K$ , such that $f(k_{n}) \in M_{n+1}$ , but $f(k_{n}) \notin M_{n}$ . We claim that an arbitrary finitely generated submodule N contains at most finitely many of the $f(k_{n})$ . To see this, let us write $M_{\infty } = \cup M_{n}$ and consider $N \cap M_{\infty }$ ; the latter is again finitely generated, as $E_{0}$ is Noetherian, and its intersection with $\{ f(k_{n}) \}$ is the same as that of N. By finite generation, we have $N \cap M_{\infty } = N \cap M_{n}$ for sufficiently large n, proving the claim, as the latter contains at most n of the $f(k_{n})$ .

Since each finitely generated submodule is Hausdorff, its finite subspaces are closed and discrete, and we deduce that $T = \{ f(k_{n}) \}$ is closed and discrete as a subspace of M, as this is true for its intersection with each finitely generated submodule. This is a contradiction, as $T = f(f^{-1}(T))$ must be compact Hausdorff as an image of a closed subspace of K, so it cannot be both infinite and discrete.

Proposition 12.8. Let $M \simeq \varinjlim M_{\alpha }$ be a filtred colimit diagram of $E_{0}$ -modules equipped with their local $\mathfrak {m}$ -adic topologies, and let K be compact Hausdorff. Then, the induced map

$$\begin{align*}\theta\colon \varinjlim \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(K, M_{\alpha}) \rightarrow \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(K, M) \end{align*}$$

is an isomorphism of abelian groups.

Proof. We first show surjectivity of $\theta $ . Suppose that $f\colon K \rightarrow M$ is a continuous map, by Lemma 12.7, it factors through a finitely generated submodule $N \subseteq M$ . If we write $N_{\alpha } = N \times _{M} M_{\alpha }$ , then since filtred colimits are exact, we have

$$\begin{align*}N \simeq \varinjlim N_{\alpha}. \end{align*}$$

As N is finitely generated and $E_{0}$ is Noetherian, it is finitely presented, and we deduce that there exists a section $N \rightarrow N_{\alpha }$ for some $\alpha $ . Then, the composite

$$\begin{align*}K \rightarrow N \rightarrow N_{\alpha} \rightarrow M_{\alpha} \end{align*}$$

determines the needed element of the filtred colimit.

For injectivity, suppose that we have a continuous map $f\colon K \rightarrow M_{\alpha }$ , such that the composite $s_{\alpha } \circ f\colon K \rightarrow M$ , where $s_{\alpha }\colon M_{\alpha } \rightarrow M$ is the canonical map, is zero. By another application of Lemma 12.7, K factors through a finitely generated submodule $N_{\alpha } \subseteq M_{\alpha }$ , and we necessarily have $N_{\alpha } \subseteq \mathrm {ker}(s_{\alpha })$ . As $N_{\alpha }$ is finitely generated, the second condition implies that we can find a larger index $\beta $ , such that the composite

$$\begin{align*}N_{\alpha} \rightarrow M_{\alpha} \rightarrow M_{\beta} \end{align*}$$

is zero. It follows that f determines the zero element of the filtred colimit, as needed.

Corollary 12.9. Let $M \simeq \varinjlim M_{\alpha }$ be a filtred colimit of $E_{0}$ -modules equipped with their local $\mathfrak {m}$ -adic topology and compatible continuous $\mathbb {G}_{n}$ -actions. Then,

$$\begin{align*}\mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, M) \simeq \varinjlim \mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, M_{\alpha}). \end{align*}$$

In particular, for any $E_{0}$ -module N, we have

$$\begin{align*}\mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, N) \simeq \varinjlim \mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, N_{\alpha}), \end{align*}$$

where the colimit is taken over the poset $N_{\alpha }$ of finitely generated submodules.

Proof. The continuous cohomology is computed by the standard cochain complex

$$\begin{align*}M \rightarrow \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, M) \rightarrow \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n} \times \mathbb{G}_{n}, M) \rightarrow \ldots \end{align*}$$

of continuous cochains. The statement follows from an application of Proposition 12.8 to each term separately, as $\mathbb {G}_{n} \times \ldots \times \mathbb {G}_{n}$ is compact Hausdorff and taking cohomology of cochain complexes commutes with filtred colimits.

12.2 Inverse limits of $E_*E$ -comodules and continuous cohomology

In this section, we give a description of derived functors of the limit

in $E_{*}E$ -comodules as cohomology of the Morava stabiliser group. The importance of these derived functors stems from the fact that they form the $E_{2}$ -page of the spectral sequence constructed in Section 11.2.

Lemma 12.10. If M is a dualisable $E_{*}E$ -comodule, then we have a canonical isomorphism

for any $s\ge 0$ , where $E_{*} / \mathfrak {m}^{k}$ is the $\mathfrak {m}$ -adic tower of $E_{*}$ .

Proof. For brevity, if

, let us write

Since we have

there is a Milnor sequence

where we have omitted subscripts for simplicity and the derived functors of the limit are taken in abelian groups.

We first claim that the $\varprojlim ^1$ -term above vanishes. Note that since $M / \mathfrak {m}^{k}M$ is finitely generated and $\mathfrak {m}$ -torsion for any $k \geq 1$ , we have a canonical isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}(M / \mathfrak{m}^{k}M) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{s}(\mathbb{G}_{n}, M/\mathfrak{m}^{k}M) \end{align*}$$

with the cohomology of the Morava stabiliser group. For $k = 1$ , we have a further isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}(M / \mathfrak{m} M) \simeq \operatorname{\mathrm{Ext}}_{E_{*}E}(E_{*}, K_{*} \otimes_{E_{*}} M) \simeq \operatorname{\mathrm{Ext}}_{E_{*}K}(K_{*}, K_{*} \otimes_{E_{*}} M) \end{align*}$$

and the group on the right is degreewise finite by Corollary 5.7. It follows by induction that $\operatorname {\mathrm {Ext}}(M_{*} / \mathfrak {m}^k M)$ is degreewise finite for each $k\ge 1$ . Therefore, the groups $\operatorname {\mathrm {Ext}}(M / \mathfrak {m}^k M)$ satisfy the Mittag-Leffler condition as k varies, so that the corresponding $\varprojlim ^1$ -term vanishes as claimed.

Consequently, we get a string of isomorphisms

Here, the last isomorphism uses that M is $\mathfrak {m}$ -adically complete as a finitely generated $E_{*}$ -module, and that taking continuous cohomology of a finitely generated profinite group commutes with taking countable inverse limits of finite modules [Reference Neukirch, Schmidt and WingbergNSW13, Section 7].

In order to pass from Lemma 12.10 to a description of the derived functors $\textstyle \varprojlim ^{s}_{E_{*}E} E_{*} / \mathfrak {m}^{k}$ , we have to understand the homology groups of

, rather than its homotopy. To do so, we will make use of the Adams condition, which involves certain filtred colimits. To commute past the latter, we will need a technical lemma stating that homotopy groups

preserve certain filtred colimits of bounded complexes. If $p> n+1$ , then the monoidal unit of

is compact, so no boundedness hypotheses are required, but this can fail for general n. In general, we still have the following result.

Lemma 12.11. Suppose $(L_{\alpha })_{\alpha }$ is a filtred system of complexes of $E_*E$ -comodules which are uniformly bounded above in the standard t-structure on ; that is, there exists an N, such that, for all $s>N$ and all $\alpha $ , we have $H_s(L_{\alpha }) = 0$ . Then the canonical comparison map

$$\begin{align*}\phi\colon \varinjlim_{\alpha} \operatorname{\mathrm{Ext}}^{s}(L_{\alpha}) \longrightarrow \operatorname{\mathrm{Ext}}^{s}(\varinjlim_{\alpha}L_{\alpha}) \end{align*}$$

is an isomorphism for any $s \in \mathbb {Z}$ .

Proof. By shifting the system $(L_{\alpha })_{\alpha }$ if necessary, we may reduce to the case of $s = 0$ . In other words, we have to show that that the canonical map

$$\begin{align*}\varinjlim_{\alpha} \ [E_*,L_{\alpha}] \longrightarrow [E_*,\varinjlim_{\alpha}L_{\alpha}] \end{align*}$$

between homotopy classes of maps in the derived $\infty $ -category, is an isomorphism.

Since $E_*$ is connective in the standard t-structure, we can then replace $L_{\alpha }$ by its connective cover $\tau _{\ge 0}L_{\alpha }$ ; that is, reduce to the case in which there exists a nonnegative integer N, such that $L_{\alpha }$ has homology concentrated in degrees $[0,N]$ for all $\alpha $ . By induction and the five-lemma, we can reduce further to the case that $L_{\alpha }$ is concentrated in a single nonnegative degree $[s,s]$ for all $\alpha $ .

Summarising these reduction steps, it remains to prove that the canonical map

$$\begin{align*}\varinjlim_{\alpha}\operatorname{\mathrm{Ext}}_{E_{*}E}^s(E_*,L_{\alpha}) \longrightarrow \operatorname{\mathrm{Ext}}_{E_{*}E}^s(E_*,\varinjlim_{\alpha}L_{\alpha}) \end{align*}$$

is an isomorphism for any filtred system of comodules $L_{\alpha } \in \operatorname {\mathrm {Comod}}_{E_*E}$ . This is clear, these $\operatorname {\mathrm {Ext}}$ -groups can be computed by the cobar complex, formation of which commutes with filtred colimits.

Proposition 12.12. For any dualisable $E_{*}E$ -comodule M, there exists a canonical isomorphism

$$\begin{align*}\textstyle\varprojlim_{E_{*}E}^s M / \mathfrak{m}^{k} M \simeq \mathrm{H}^s_{\operatorname{\mathrm{cts}}}(\mathbb{G}_n,E_*E \otimes_{E_{*}} M) \end{align*}$$

between the derived functors of the limit in comodules and the continuous cohomology of the Morava stabiliser group with coefficients in $E_{*}E \otimes _{E_{*}} M$ equipped with its local $\mathfrak {m}$ -adic topology.

Proof. We have

which we can further rewrite as

where the tensor product is the derived one. Writing $E_{*}E \simeq \varinjlim N_{\alpha }$ as a filtred colimit of dualisable comodules, we have

Here, the first isomorphism uses that the derived tensor product commutes with filtred colimits and the second one is Lemma 12.11. The third isomorphism uses that tensoring with a dualisable object commutes with limit, the fourth one is Lemma 12.10, while the fifth one is Corollary 12.9.

Remark 12.13. The relationship between derived functors of the limit and derived completion in the context of comodules over a flat Hopf algebroid is studied further in [Reference Barthel, Heard and ValenzuelaBHV20].

12.3 The inverse limit spectral sequence and its convergence

In this subsection, we study the convergence of the inverse limit spectral sequence based on Morava E-theory and combine the previous results in a spectral sequence computing the (uncompleted) E-homology of the K-local sphere spectrum from continuous group cohomology with coefficients in the (uncompleted) cooperations $E_*E$ .

Proposition 12.14. If $R=E$ is Morava E-theory and is a tower of E-local spectra, then the spectral sequence of Example 11.22 converges conditionally and strongly, and has a horizontal vanishing line at the $E_r$ -page for some $r\ge 2$ .

Proof. By Lemma 11.8 and assumption on $X^{\alpha }$ , the modified Adams tower $(X_i^{\alpha })$ is E-local for all i. Therefore, the proof of the smash product theorem due to Hopkins and Ravenel [Reference RavenelRav92, Theorem 7.5.6] yields a constant N independent of $\alpha $ , such that

is null for all $\alpha $ (see [Reference Hovey and StricklandHS05b, Theorem 5.10]). Consequently,

(12.15)

is null as well, so [Reference BoardmanBoa99] shows that the spectral sequence is conditionally convergent. Similarly, we obtain the horizontal vanishing line from (12.15), which in turn gives strong convergence.

Theorem 12.16. If

is a tower of E-local spectra, then there is a strongly convergent spectral sequence

with a horizontal vanishing line at the $E_r$ -page for some $r\ge 2$ . In particular, this spectral sequence specialises to:

(12.17)

Proof. The spectral sequence was constructed in Theorem 11.14, see also Example 11.22, while the convergence properties were established in Proposition 12.14. The final statement follows by applying this spectral sequence to a cofinal tower of E-local generalised type n Moore spectra, as in [Reference Hovey and StricklandHS99, Section 4]. The identification of the $E_2$ -page in terms of continuous cohomology was proven in Proposition 12.12.

Remark 12.18. The spectral sequence (12.17) may be thought of as an $E_*$ -homology version of the K-local E-based Adams spectral sequence for the sphere, which has signature

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^s(\mathbb{G}_n,E_*)_t \implies \pi_*L_{K}S^0 \end{align*}$$

and is also strongly convergent. In contrast, working with completed $E_*$ -homology would result in an isomorphism $E_* \simeq E_*^{\vee }L_{K}S^0 \simeq \mathrm {H}_{\operatorname {\mathrm {cts}}}^*(\mathbb {G}_n,E_*^{\vee }E_*)$ . This amply highlights the extra information contained in the terms $\mathrm {H}_{\operatorname {\mathrm {cts}}}^*(\mathbb {G}_n,E_*E)$ .

13 Digression: Cohomology of $\mathbb {G}_{n}$ as $\operatorname {\mathrm {Ext}}$ in comodules

In Lemma 12.10, we have expressed the continuous cohomology of the Morava stabiliser group with coefficients in a dualisable $E_{*}E$ -comodule M in terms of the homotopy groups of a derived completion. In this short section, we use a form of local duality in the context of comodules to express it as an $\operatorname {\mathrm {Ext}}$ -groups between actual comodules, rather than objects of the derived $\infty $ -category. Using this calculation, we define a comparison map between $\operatorname {\mathrm {Ext}}$ -groups and continuous cohomology.

Let $I_k = (p,v_1,\ldots ,v_{k-1})$ be the k-th invariant chromatic ideal in $E_*$ ; in particular, $I_n = \mathfrak {m}$ . We define $E_* = E_*/I_0^{\infty }$ and then iteratively construct $E_*E$ -comodules via the cofibre sequences

(13.1) $$ \begin{align} E_{*} / I_k^{\infty} \rightarrow v_{k}^{-1} E_{*} / I_k^{\infty} \rightarrow E_{*} / I_{k+1}^{\infty} \end{align} $$

in . Note that $E_{*} / I_k^{\infty } \simeq \varinjlim E_{*} / v_{0}^{l_{0}}, \ldots , v_{k-1}^{l_{k-1}}$ , where the colimit is taken over a set of indices with $l_{i} \rightarrow \infty $ . For the constituent pieces, we have the following self-duality result:

Lemma 13.2. In the derived category of $E_{*}E$ -comodules, the comodule $E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots , v_{k}^{i_{k}}$ is self-dual with a shift in the sense that there exists an equivalence

$$\begin{align*}D(E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k}^{i_{k}}) \simeq \Sigma^{-k} E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k}^{i_{k}}, \end{align*}$$

where $DX = F(X, E_{*})$ denotes the monoidal dual.

Proof. We prove this by induction on k, where $k = -1$ is clear, since $E_{*}$ is the monoidal unit.

Now assume that the statement is known for $E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots , v_{k-1}^{i_{k-1}}$ . Multiplication by $v_{k}^{i_{k}}$ induces a cofibre sequence

$$\begin{align*}E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k-1}^{i_{k-1}} \rightarrow E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k-1}^{i_{k-1}} \rightarrow E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k}^{i_{k}} \end{align*}$$

which after taking duals yields a cofibre sequence

$$\begin{align*}D(E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k}^{i_{k}}) \rightarrow D(E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k-1}^{i_{k-1}}) \rightarrow D(E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k-1}^{i_{k-1}}). \end{align*}$$

By the inductive assumption, this sequence can be rewritten as

$$\begin{align*}D(E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k}^{i_{k}}) \rightarrow \Sigma^{k-1} E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k-1}^{i_{k-1}} \rightarrow \Sigma^{k-1} E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots, v_{k-1}^{i_{k-1}}. \end{align*}$$

The self-map of $\Sigma ^{k-1} E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots , v_{k-1}^{i_{k-1}} \rightarrow \Sigma ^{k-1} E_{*} / v_{0}^{i_{0}}, v_{1}^{i_{1}}, \ldots , v_{k-1}^{i_{k-1}}$ appearing on the right cannot be nonzero, since it is a dual to the nonzero class $v_{k}^{i_{k}}$ . It follows that it must be itself a unit times $v_{k}^{i_{k}}$ since there is nothing else in this degree (see, for example [Reference RavenelRav03, Theorem 4.3.2(b)]). The assertion then follows.

Lemma 13.3. If M is a finitely generated $E_{*}E$ -comodule, then its derived comodule completion of M is given by

where on the left-hand side we have used the derived tensor product of comodules.

Proof. This is proven in [Reference Barthel, Heard and ValenzuelaBHV20, Proposition 2.25]

The next result is an incarnation of local duality for comodules [Reference Barthel, Heard and ValenzuelaBHV18, Section 5], relating local cohomology (derived torsion) and local homology (derived completion), combined with Lemma 12.10.

Theorem 13.4. Let M be a finitely generated $E_{*}E$ -comodule. Then, there exists an isomorphism

$$\begin{align*}\operatorname{\mathrm{Ext}}^{n+s}_{E_{*}E}(E_{*} / I_n^{\infty}, M) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{s}(\mathbb{G}_{n}, M) \end{align*}$$

between $\operatorname {\mathrm {Ext}}$ -groups in comodules and the cohomology of $\mathbb {G}_{n}$ , for any $s\ge 0$ .

Proof. As noted before, we have $E_{*} / I_n^{\infty } \simeq \varinjlim E_{*} / v_{0}^{k_{0}}, \ldots , v_{n-1}^{k_{n-1}}$ , where the colimit is taken over a set of indices with $k_{i} \rightarrow \infty $ . By the duality equivalence of Lemma 13.2, we have

In light of Lemma 13.3, the latter term is equivalent to

. It follows that

$$\begin{align*}\operatorname{\mathrm{Ext}}^{n+s}_{E_{*}E}(E_{*} / I_n^{\infty}, M) \simeq \varprojlim \operatorname{\mathrm{Ext}}^{s}_{E_{*}E}(E_{*}, M/v_{0}^{k_{0}}, \ldots, v_{n-1}^{k_{n-1}}), \end{align*}$$

up to possible $\varprojlim ^{1}$ -terms. However, all of the Ext groups on the right are finite, since M is finitely generated, so these $\varprojlim ^{1}$ -terms vanish. We then deduce as in Lemma 12.10 that

$$\begin{align*}\operatorname{\mathrm{Ext}}^{n+s}_{E_{*}E}(E_{*} / I_n^{\infty}, M) \simeq \varprojlim \operatorname{\mathrm{Ext}}_{E_{*}E}^{s}(E_{*}, M / v_{0}^{k_{0}}, \ldots, v_{n-1}^{k_{n-1}}) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{s}(\mathbb{G}_{n}, M), \end{align*}$$

which is what we wanted to show.

The boundary maps $\delta _k\colon E_*/I_{k+1}^{\infty } \to \Sigma E_*/I_{k}^{\infty }$ associated with the cofibre sequences (13.1) compose to give a ‘residue map’ in the derived category:

For any finitely generated $E_*E$ -comodule N, the map $\delta $ induces a natural map on Ext-groups that fits, for any s, into a commutative square

(13.5)

Here, the left vertical isomorphism is by duality, while the right vertical isomorphism is established as in the proof of the previous theorem. Unwinding the construction, the bottom horizontal map is then induced by the canonical completion map

.

Definition 13.6. For a finitely generated $E_*E$ -comodule N, we define the comparison map $\alpha _N$ as the composite

$$\begin{align*}\alpha_N\colon \operatorname{\mathrm{Ext}}^{s}_{E_{*}E}(E_{*}, N) \to \operatorname{\mathrm{Ext}}^{n+s}_{E_{*}E}(E_{*} / I_n^{\infty}, N) \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^{s}(\mathbb{G}_{n}, N) \end{align*}$$

of the map in (13.5) and the isomorphism of Theorem 13.4.

Note that, by construction, the maps $\alpha _{N}$ are natural and compatible with the long exact sequences of $\operatorname {\mathrm {Ext}}$ -groups and cohomology.

Remark 13.7. Alternatively, it is possible to define the comparison map $\alpha _M$ directly using the cobar complex. More precisely, one can show that if M is a finitely generated $E_{*}E$ -comodule, then the differentials in the cobar complex

$$\begin{align*}M \rightarrow E_{*}E \otimes_{E_{*}} M \rightarrow E_{*}E \otimes_{E_{*}} E_{*}E \otimes_{E_{*}} M \rightarrow \ldots \end{align*}$$

respect the $\mathfrak {m}$ -adic filtration (even though they are not $E_{*}$ -linear). The completion of the cobar complex is exactly the cochain complex computing continuous $\mathbb {G}_{n}$ -cohomology, and the induced map on homology can be shown to be exactly $\alpha _{M}$ .

14 Algebraic chromatic splitting conjecture

In this penultimate section, we use the comparison map of the previous section to compute the zeroth derived limit as $\varprojlim ^{0}_{E_{*}E} E_{*} / \mathfrak {m}^{k} \simeq E_{*} \otimes _{\mathbb {Z}} \mathbb {Z}_{p}$ . This result should be viewed in light of Hopkins’s algebraic chromatic splitting conjecture, see [Reference PetersonPet, Section 14], which we briefly review for context.

Notation 14.1. To simplify notation, if N is a finitely generated $E_{*}E$ -comodule, we sometimes use abbreviations and .

14.1 The algebraic chromatic splitting conjecture

Motivated by computations in height 2, this conjecture was formulated by Hopkins and recorded later in [Reference PetersonPet, Conjecture 134]Footnote 3 as well as [Reference Barthel, Schlank and StapletonBSS20, Conjecture 6.10], and studied further in [Reference Barthel and HeardBH18]. To state it, we first recall the construction of the class $\zeta \in \pi _{-1}L_{K}S^0$ due to Devinatz and Hopkins [Reference Devinatz and HopkinsDH04, Section 8].

If we write $\mathbb {G}_n^1$ for the kernel of the reduced determinant map $\det \colon \mathbb {G}_n \to \mathbb {Z}_p$ , there is a residual action of $\mathbb {Z}_p$ on $E_n^{h\mathbb {G}_n^1}$ . For t is a topological generator of $\mathbb {Z}_p$ , we then obtain a fibre sequence of spectra

The composition $\delta \circ \eta \colon S^0 \to L_{K}S^0$ of the unit map with the boundary map gives rise to an element $\zeta \in \pi _{-1}L_{K}S^0$ . In [Reference Devinatz and HopkinsDH04, Proposition 8.2], Devinatz and Hopkins prove a result originally due to Hopkins and Miller, saying that $\zeta $ is nontrivial as long as the height $n>0$ .

Conjecture 14.2 (Algebraic chromatic splitting conjecture).

For all heights $n \ge 2$ and sufficiently large p, there are isomorphisms of $E_*E$ -comodules

$$\begin{align*}\textstyle\varprojlim_{E_{*}E}^sE_*/(p,\ldots,v_{n-2},v_{n-1}^i) \simeq \begin{cases} E_*/(p,\ldots,v_{n-2}) & s=0 \\ v_{n-1}^{-1}E_*/(p,\ldots,v_{n-2}) & s=1 \\ 0 & \mathrm{otherwise.} \end{cases} \end{align*}$$

Moreover, these isomorphisms are topologically realised by the unit map $\iota \colon S^0 \to L_{K}S^0$ and the map $\zeta \colon S^{-1} \to L_{K}S^0$ , respectively.

Remark 14.3. As the name suggests, the algebraic chromatic splitting conjecture provides an algebraic counterpart to Hopkins’s chromatic splitting conjecture [Reference HoveyHov95, Conjecture 4.2] in the edge case: If the algebraic chromatic splitting conjecture holds at height n and prime p, then the maps $\iota $ and $\zeta $ induce a splitting

$$\begin{align*}(\iota,\zeta)\colon L_{n-1}F \oplus \Sigma^{-1}L_{n-1}F \simeq L_{n-1}L_{K}F \end{align*}$$

for any finite spectrum F of type $n-1$ . Indeed, the conclusion of the algebraic chromatic splitting conjecture forces the inverse limit sequence (11.15) for $L_{K}F$ to collapse at the $E_2$ -page, thereby showing $(\iota ,\zeta )$ is an $E_*$ -isomorphism, and hence an E-local equivalence.

Example 14.4. In Section 15, we verify a height 1 variant of the algebraic chromatic splitting conjecture at any prime (see, in particular, Theorem 15.12 and also [Reference PetersonPet, Section 14]). The appearance of the additional tensor factors is the only reason we excluded the case of height 1 from the statement of the algebraic chromatic splitting conjecture above.

14.2 The comparison map in degree 0

We work with Notation 14.1. Our goal is to study the comparison map $\operatorname {\mathrm {Ext}}^{s}(M) \rightarrow \mathrm {H}^{s}(M)$ , constructed in Definition 13.6. We focus on the particular case when $s = 0$ ; note that in this case, this map is always injective, as both the source and target are abelian subgroups of M.

Thus, the real question is how far this comparison map is from being surjective. When M is the monoidal unit, we have the following folklore result of Hopkins.

Lemma 14.5 (Hopkins).

We have $\mathrm {H}^{0}(E_{*}) \simeq \mathbb {Z}_{p}$ and the map $\operatorname {\mathrm {Ext}}^{0}(E_{*}) \rightarrow \mathrm {H}^{0}(E_{*})$ is a p-completion; that is, it induces an isomorphism $\mathbb {Z}_{p} \otimes _{\mathbb {Z}} \operatorname {\mathrm {Ext}}^{0}(E_{*}) \simeq \mathrm {H}^{0}(E_{*})$ .

Proof. The first part is [Reference Bobkova and GoerssBG18, Lemma 1.33]. The second part follows from the fact that $\operatorname {\mathrm {Ext}}^{0}(E_{*}) \simeq \mathbb {Z}_{(p)}$ , as in both cases, the relevant invariants are generated by the unit of the Lubin–Tate ring.

Lemma 14.6. The map $\operatorname {\mathrm {Ext}}^{1}(E_{*}) \rightarrow \mathrm {H}^{1}(E_{*})$ is a monomorphism.

Proof. Since it vanishes rationally, the source of this map is p-torsion. For a given $x \in \operatorname {\mathrm {Ext}}^{1}(E_{*})$ , we can thus find a k and $y \in \operatorname {\mathrm {Ext}}^{0}(E_{*}/p^{k})$ so that x can be written as $x = \delta (y)$ , where $\delta $ denotes the boundary homomorphism. We have a commutative diagram

with exact rows. Thus, it is enough to show that if the image $\widetilde {y} \in \mathrm {H}^{0}(E_{*}/p^{k})$ of y can be lifted to $\mathrm {H}^{0}(E_{*})$ , then y can be lifted to $\operatorname {\mathrm {Ext}}^{0}(E_{*})$ . By Lemma 14.5, the latter two groups are isomorphic to, respectively, $\mathbb {Z}_{p}$ and $\mathbb {Z}_{(p)}$ .

By multiplying by an appropriate unit $\sigma $ in the p-adics congruent to $1$ modulo $p^{k}$ , and replacing the chosen lift $\widetilde {z} \in \mathrm {H}^{0}(E_{*}) \simeq \mathbb {Z}_{p}$ of $\widetilde {y}$ by $\sigma \widetilde {z}$ , we can assume that $\widetilde {z} \in \mathbb {Z}_{(p)}$ . It follows that y can be lifted to $\operatorname {\mathrm {Ext}}^{0}(E_{*})$ , which is what we wanted.

Our goal is to use an inductive argument, building on the calculation of invariants of $E_{*}$ due to Hopkins and extending it to a larger class of comodules. The starting point is the following class.

Definition 14.7. We say a finitely generated $E_{*}E$ -comodule M is pure if it belongs to the smallest class of comodules closed under extensions and containing all shifts of $E_{*}$ .

Remark 14.8. Any pure M is finitely generated and projective over $E_{*}$ , and so dualisable. It follows that if

$$\begin{align*}0 \rightarrow K \rightarrow M \rightarrow N \rightarrow 0 \end{align*}$$

is a short exact sequence of pure comodules, then it is split over $E_{*}$ , so that the induced sequence

$$\begin{align*}0 \rightarrow N^{\operatorname{\mathrm{dual}}} \rightarrow M^{\operatorname{\mathrm{dual}}} \rightarrow K^{\operatorname{\mathrm{dual}}} \rightarrow 0 \end{align*}$$

of linear duals is again exact. We deduce that the class of pure comodules is closed under taking duals.

Remark 14.9. It is plausible that it follows from the arguments of Hovey and Strickland, who establish an analogue of the Landweber filtration for $E_{*}E$ -comodules [Reference Hovey and StricklandHS05a], that all comodules finitely generated and projective over $E_{*}$ are pure in the sense of Definition 14.7. We did not check whether this is true, as we do not need this fact in our arguments.

Lemma 14.10. The category of $E_{*}E$ -comodules is generated under colimits by pure comodules.

Proof. Since $E \simeq \varinjlim E_{\alpha }$ is a filtred colimit of finite spectra, it follows formally that the category of $E_{*}E$ -comodules is generated under colimits by shifts of comodules of the form $E_{*} E_{\alpha }$ [Reference HoveyHov04a, Proposition 1.4.4].

Furthermore, we claim that since the $E_{\alpha }$ only have even cells, the resulting comodules $E_{*} E_{\alpha }$ are pure. Using a cell decomposition of $E_{\alpha }$ and the associated long exact sequences in homology, which is short exact here, we deduce that each $E_{*}E_{\alpha }$ is a comodule which can be obtained using iterated extensions of shifts of $E_{*}$ and so is pure.

Recall that a $E_{*}E$ -comodule is dualisable if and only if the underlying $E_*$ -module is finitely generated and projective.

Theorem 14.11. If N is a dualisable $E_{*}E$ -comodule, then

  1. (1) $\operatorname {\mathrm {Ext}}^{0}(N)$ is a finitely generated $\mathbb {Z}_{(p)}$ -module and

  2. (2) the map $\alpha _{N}\colon \operatorname {\mathrm {Ext}}^{0}(N) \rightarrow \mathrm {H}^{0}(N)$ is a p-completion, that is, it induces an isomorphism $\operatorname {\mathrm {Ext}}^{0}(N) \otimes _{\mathbb {Z}} \mathbb {Z}_{p} \simeq \mathrm {H}^{0}(N)$ .

Proof. For $N = E_{*}$ or its shifts, this is Lemma 14.5.

We first claim that the result is true for comodules C which are pure in the sense of Definition 14.7. By induction on rank, we can assume that we have a short exact sequence

$$\begin{align*}0 \rightarrow E_{*} \rightarrow C \rightarrow C^{\prime} \rightarrow 0 \end{align*}$$

and that the result already holds for $C^{\prime }$ . The long exact sequence of $\operatorname {\mathrm {Ext}}$ -groups implies that $\operatorname {\mathrm {Ext}}^{0}(C)$ is a finitely generated module over $\mathbb {Z}_{(p)}$ . Thus, we have a commutative diagram

where the top row is again exact, since $\mathbb {Z}_{p}$ is flat. By induction on rank, counting from the left, the first and third vertical maps are isomorphisms. By Lemma 14.6, the fourth one is a monomorphism, as $\mathbb {Z}_{p} \otimes \operatorname {\mathrm {Ext}}^{1}(E_{*}) \simeq \operatorname {\mathrm {Ext}}^{1}(E_{*})$ because the latter group is p-torsion. We deduce that the second one is an isomorphism using the five-lemma, which was our claim.

Now suppose that N is an arbitrary dualisable comodule; by Lemma 14.10, we can find a surjection $C \rightarrow N$ from a pure comodule. By taking duals, we can assume that we instead have a monomorphism $N \hookrightarrow C$ , where C is again pure by Remark 14.8. Since we already know $\operatorname {\mathrm {Ext}}^{0}(C)$ and $\mathrm {H}^{0}(C)$ are free finitely generated over, respectively, $\mathbb {Z}_{(p)}$ and $\mathbb {Z}_{p}$ , we deduce that the same is true for their submodules $\operatorname {\mathrm {Ext}}^{0}(N)$ and $\mathrm {H}^{0}(N)$ , proving  $(1)$ .

Let us denote the cokernel of $N \hookrightarrow C$ by $C^{\prime }$ . We then have another commutative diagram

By what we have proven above, the middle map is an isomorphism as well. Since the right one is injective, we deduce from the four-lemma that the left one is surjective, ending the argument.

Remark 14.12. One would like to prove that Theorem 14.11 holds for all finitely generated comodules, rather than only the finitely generated projective ones. It is possible this more general result can be deduced formally from the projective case, but we were not able to do so.

The key ingredient in the above proof is the calculation of $\mathrm {H}_{\operatorname {\mathrm {cts}}}^{0}(\mathbb {G}_{n}, E_{*})$ ; it seems likely that the version for arbitrary comodules would follow from a more general calculation of $\mathrm {H}_{\operatorname {\mathrm {cts}}}^{0}(\mathbb {G}_{n}, E_{*} / I_{k})$ by Landweber filtration arguments.

14.3 The comodule completion of Morava E-theory

We now come to the main theorem of this section. One may view the computation of this inverse limit at all heights and primes as uniform evidence for the validity for the algebraic chromatic splitting conjecture, and hence of the chromatic splitting conjecture itself.

Theorem 14.13. We have

$$\begin{align*}\textstyle\varprojlim_{E_{*}E} E_{*} / \mathfrak{m}^{k} \simeq \mathrm{H}_{\operatorname{\mathrm{cts}}}^0(\mathbb{G}_n,E_*E) \simeq E_{*} \otimes _{\mathbb{Z}} \mathbb{Z}_{p}, \end{align*}$$

where the left-hand side is the limit in the category of $E_{*}E$ -comodules.

Proof. The first isomorphism is an instance of Proposition 12.12. By Corollary 12.9, if $M_{\alpha }$ is a filtred diagram of dualisable $E_{*}E$ -comodules, such that $\varinjlim M_{\alpha } \simeq E_{*}E$ , then

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^0(\mathbb{G}_n,E_*E) \simeq \varinjlim \mathrm{H}_{\operatorname{\mathrm{cts}}}^0(\mathbb{G}_n, M_{\alpha}) \simeq \varinjlim \operatorname{\mathrm{Ext}}^{0}_{E_{*}E}(E_{*}, M_{\alpha}) \otimes_{\mathbb{Z}} \mathbb{Z}_{p} \simeq E_{*} \otimes_{\mathbb{Z}} \mathbb{Z}_{p} \end{align*}$$

where the second isomorphism is Theorem 14.11. This ends the argument.

Remark 14.14. Since $E_{*} S^{0}_{p} \simeq E_{*} \otimes _{MU_{*}} MU_{*}S^{0}_{p} \simeq E_{*} \otimes \mathbb {Z}_{p}$ , one can rephrase Theorem 14.13 as saying that $\varprojlim ^{0} E_{*} / \mathfrak {m}^{k} \simeq E_{*}S^{0}_{p}$ , which relates this result to the topological chromatic splitting conjecture.

Remark 14.15. There is a short exact sequence of $E_*E$ -modules

Applying the functor

and considering the induced long exact sequence in cohomology, we deduce that $v_{n-1}$ acts on

injectively for $s=0$ and bijectively for $s>0$ . This provides further evidence for Conjecture 14.2.

15 Cooperations at height 1

In the previous section, we discussed the importance of the derived functors of the limit in the category of comodules and its relation to the chromatic splitting conjecture. In Proposition 12.12, we gave an explicit formula for these in the form of an isomorphism

$$\begin{align*}\textstyle\varprojlim^{s}_{E_{*}E} E_{*} / \mathfrak{m}^{k}E_{*} \simeq \mathrm{H}^{s}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{n}, E_{*}E), \end{align*}$$

where on the left-hand side we have the s-th derived functor of the limit in $E_{*}E$ -comodules and the right-hand side we have continuous cohomology of the Morava stabiliser group. To make use of this, we would like to understand $E_{*}E$ as a $\mathbb {G}_{n}$ -representation; in this section, we do so for $n = 1$ .

Warning 15.1. Let us warn the reader again that we are interested in the uncompleted cooperations; that is, $E_{*}E = \pi _{*}(E \otimes E)$ . The description of the completed cooperations

is well-known, as we have $E^{\vee }_*E \simeq \operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{n}, E_{*})$ at any height by a result of Strickland [Reference StricklandStr00] or [Reference HoveyHov04b].

Notation 15.2. Instead of the Honda formal group law, it will be convenient to work with the multiplicative formal group law over $\mathbb {F}_{p}$ , which we denote by $\Gamma $ . This is of height 1, so that the Lubin–Tate ring is isomorphic to the p-adics, with the universal deformation the multiplicative formal group law over $\mathbb {Z}_{p}$ . By the uniqueness part of the Goerss–Hopkins–Miller theorem, the Lubin–Tate spectrum associated to this universal deformation is given by

the p-complete complex K-theory. The action of $\mathbb {G}_{1}$ is given by Adams operations.

Lemma 15.3. There is an isomorphism

$$\begin{align*}E_{*}E \simeq E_{*}KU \otimes_{\mathbb{Z}} \mathbb{Z}_{p} \end{align*}$$

of $\mathbb {G}_{1}$ -representations, where on the right-hand side the action is trivial on the $\mathbb {Z}_{p}$ -factor.

Proof. We have $KU_{*} \simeq \mathbb {Z}[u^{\pm 1}]$ and $E_{*} \simeq KU_{*} \otimes \mathbb {Z}_{p}$ , which is flat over $KU_*$ . It then follows from flatness that we have an isomorphism

$$\begin{align*}E_{*}E \simeq E_{*}KU \otimes_{\mathbb{Z}} \mathbb{Z}_{p} \end{align*}$$

induced by the multiplication map

$$\begin{align*}(E \otimes KU) \otimes_{KU} E \rightarrow E \otimes E. \end{align*}$$

Since this multiplication map is $\mathbb {G}_{1}$ -equivariant with respect to the action on the left E factor, this is, in fact, an isomorphism of representations.

Corollary 15.4. There is an isomorphism

$$\begin{align*}\mathrm{H}^{s}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, E_{*}E) \simeq \mathrm{H}^{s}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, E_{*}KU) \otimes_{\mathbb{Z}} \mathbb{Z}_{p}. \end{align*}$$

Proof. Let us write for brevity. As $\mathbb {Z}_{p}$ is flat, it can be written as a filtred colimit $\mathbb {Z}_{p} \simeq F_{\alpha }$ of finitely generated, free abelian groups by Lazard’s theorem. We then have

$$\begin{align*}\mathrm{H}^{s}(E_{*}E) \simeq \mathrm{H}^{s}(E_{*}KU \otimes_{\mathbb{Z}} \mathbb{Z}_{p}) \simeq \mathrm{H}^{s}(\varinjlim E_{*}KU \otimes_{\mathbb{Z}} F_{\alpha}) \simeq \varinjlim \mathrm{H}^{s}(E_{*}KU \otimes_{\mathbb{Z}} F_{\alpha}), \end{align*}$$

where the last equivalence used Corollary 12.9, and further

$$\begin{align*}\varinjlim \mathrm{H}^{s}(E_{*}KU \otimes_{\mathbb{Z}} F_{\alpha}) \simeq \varinjlim \mathrm{H}^{s}(E_{*}KU) \otimes_{\mathbb{Z}} F_{\alpha} \simeq \mathrm{H}^{s}(E_{*}KU) \otimes_{\mathbb{Z}} \mathbb{Z}_{p}, \end{align*}$$

where the first equivalence used additivity of cohomology.

It follows from Corollary 15.4 that to understand the cohomology with coefficients in $E_{*}E$ , it is enough to understand $E_{*}KU$ . As we are working with coefficients in the homology of a spectrum rather than an arbitrary $\mathbb {G}_{1}$ -module, we have a canonical family of invariants. To be more precise, we have a Hurewicz homomorphism

$$\begin{align*}KU_{*} \rightarrow E_{*}KU \end{align*}$$

whose image necessarily consists of $\mathbb {G}_{1}$ -invariants. It follows that the cohomology groups

$$\begin{align*}\mathrm{H}^{*}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, E_{*}KU) \end{align*}$$

are $2$ -periodic. As they’re also even, as $E_{*}KU$ is, it is enough to determine the cohomology with coefficients in $E_{0}KU$ .

Lemma 15.5. The composite

$$\begin{align*}E_{0}KU \rightarrow E_{0}^{\vee}KU \simeq E_{0}^{\vee}E \simeq \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{Z}_{p}) \end{align*}$$

is injective.

Proof. Note that by Landweber exactness, we have

$$\begin{align*}E_{0}KU \simeq \mathbb{Z}_{p} \otimes _{\mathbb{Z}} KU_{0}KU. \end{align*}$$

This is flat over $\mathbb {Z}_{p}$ , and we deduce from Proposition 8.6 that the above composite can be identified with a p-completion map. By a result of Adams, Harris and Switzer, $KU_{0}KU$ is free as an abelian group [Reference Adams, Harris and SwitzerAHS71]. It follows that the p-completion map

$$\begin{align*}\mathbb{Z}_{p} \otimes_{\mathbb{Z}} KU_{0}KU \rightarrow (\mathbb{Z}_{p} \otimes_{\mathbb{Z}} KU_{0}KU)^{\vee}_{p} \simeq (KU_{0}KU)^{\vee}_{p} \simeq E_{0}^{\vee}E \end{align*}$$

is injective as needed.

The completion map of Lemma 15.5 is $\mathbb {G}_{1}$ -equivariant, and we deduce that $E_{0}KU$ is naturally a subrepresentation of $\operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, \mathbb {Z}_{p})$ . On the latter, $\mathbb {G}_{1}$ acts by right multiplication on the source. Our goal is to describe the given subrepresentation.

By unwrapping the definitions, the map of Lemma 15.5 can be described explicitly. By standard results about weakly periodic Landweber exact homology theories, $KU_{0}KU$ is the algebra classifying automorphisms of the multiplicative formal group law. If $g \in \mathbb {G}_{1}$ is an automorphism over the p-adics, then we can write

$$\begin{align*}g(x) = \sum_{i} b_{i}(g) x^{i}, \end{align*}$$

where the $b_{i}$ depend continuously on g. The above expression defines an automorphism of the multiplicative formal group law over $\operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, \mathbb {Z}_{p})$ ; this is the automorphism classified by the injective map

$$\begin{align*}KU_{0}KU \rightarrow \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{Z}_{p}). \end{align*}$$

Combined with Lemma 15.5, this proves the following.

Proposition 15.6. The ring $E_{0}KU$ is the $\mathbb {Z}_{p}$ -subalgebra of $\operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, \mathbb {Z}_{p})$ generated by the functions $b_{i}\colon \mathbb {G}_{1} \rightarrow \mathbb {Z}_{p}$ for $i \geq 1$ as well as $b_{1}^{-1}$ .

As we work with the multiplicative formal group law, these functions $b_{i}$ can be made explicit. Assume first that $a \in \mathbb {Z}$ , so that the corresponding multiple of the identity of the multiplicative formal group law is given by

$$\begin{align*}[a](x) = (1+x)^{a}-1 = \sum^{\infty}_{k> 0} {a \choose k} x^{k}. \end{align*}$$

The last expression makes sense even if a is a p-adic integer, where we take

$$\begin{align*}{a \choose k} = \frac{a(a-1)\ldots(a-k+1)}{k!}, \end{align*}$$

and the sum is now possibly infinite. One can check that these are automorphisms of the multiplicative formal group law even if a is p-adic, so that the identification

$$\begin{align*}\mathbb{Z}_{p}^{\times} \simeq \mathbb{G}_{1} \end{align*}$$

is given by $a \mapsto [a](x) = \sum ^{\infty }_{k> 0} {a \choose k} x^{k}$ . Thus, Proposition 15.6 can be stated in the following more explicit form.

Proposition 15.7. The algebra $E_{0}KU$ is the $\mathbb {Z}_{p}$ -subalgebra of $\operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, \mathbb {Z}_{p})$ generated by the functions $b_{i}(a) = {a \choose i}$ for $i \geq 1$ as well as $b_{1}^{-1}(a) = \frac {1}{a}$ .

Remark 15.8. The functions $b_{i}$ appearing in Proposition 15.7 are well-known to p-adic analysts. By a fundamental theorem of Mahler, any continuous p-adic function on $\mathbb {Z}_{p}$ can be written as an infinite convergent sum of the $b_{i}$ -s in a unique way [Reference MahlerMah58].

This immediately implies the following calculation.

Proposition 15.9. We have $\mathrm {H}^{0}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, E_{0}KU) \simeq \mathbb {Z}_{p}$ .

Proof. This is immediate from Proposition 15.7, as the only functions $\mathbb {G}_{1} \rightarrow \mathbb {Z}_{p}$ invariant under translation are the constants.

To compute higher cohomology groups, it is convenient to observe that they are necessarily rational.

Lemma 15.10. The groups $\mathrm {H}^{i}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, E_{0}KU)$ are rational vector spaces for $i> 0$ .

Proof. Since the inclusion $E_{0}KU \hookrightarrow \operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, \mathbb {Z}_{p})$ is an isomorphism after p-completion, as we observed in the proof of Lemma 15.5, we deduce that it is an isomorphism modulo p. It follows that

$$\begin{align*}\mathrm{H}^{i}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, E_{0}KU \otimes_{\mathbb{Z}_{p}} \mathbb{F}_{p}) \simeq \mathrm{H}^{i}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \operatorname{\mathrm{map}}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{F}_{p})) \end{align*}$$

and the right-hand side vanishes for $i> 0$ . The long exact sequence of cohomology associated to

$$\begin{align*}0 \rightarrow E_{0}KU \rightarrow E_{0}KU \rightarrow E_{0}KU \otimes_{\mathbb{Z}_{p}} \mathbb{F}_{p} \rightarrow 0, \end{align*}$$

where the first map is multiplication by p, gives the required result.

Proposition 15.11. We have

$$\begin{align*}\mathrm{H}^{1}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, E_{0}KU) \simeq \mathbb{Q}_{p} \end{align*}$$

and the higher cohomology groups vanish.

Proof. By Lemma 15.10, all cohomology groups of positive degree are rational, so that we can replace $E_{0}KU$ by $\mathbb {Q}_{p} \otimes _{\mathbb {Z}_{p}} E_{0}KU$ without changing these. The cohomology with the coefficients in the latter can be computed directly.

As each binomial coefficient $b_{i}(a) = {a \choose i}$ is a polynomial in a with rational coefficients, we deduce from Proposition 15.7 that $\mathbb {Q}_{p} \otimes _{\mathbb {Z}_{p}} E_{0}KU$ can be identified with the $\mathbb {Q}_{p}$ -subalgebra of $\operatorname {\mathrm {map}}_{\operatorname {\mathrm {cts}}}(\mathbb {G}_{1}, \mathbb {Q}_{p})$ generated by $b_{1}(a) = a$ and its inverse.

It follows that there is an isomorphism of representations

$$\begin{align*}\mathbb{Q}_{p} \otimes_{\mathbb{Z}_{p}} E_{0}KU \simeq \mathbb{Q}_{p}[b^{\pm 1}], \end{align*}$$

where $b = b_{1}$ and the action is determined by $g \cdot b = gb$ for $g \in \mathbb {G}_{1}$ . This decomposes as a direct sum of character representations

$$\begin{align*}\mathbb{Q}_{p}[b^{\pm 1}] \simeq \bigoplus _{k \in \mathbb{Z}} \mathbb{Q}_{p}(k), \end{align*}$$

where we identify $\mathbb {Q}_{p}(k)$ with the subrepresentation generated by $b^{k}$ . It follows that

$$\begin{align*}\mathrm{H}^{i}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{Q}_{p}[b^{\pm 1}]) \simeq \bigoplus_{k \in \mathbb{Z}} \mathrm{H}^{i}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{Q}_{p}(k)). \end{align*}$$

Let $U \subseteq \mathbb {G}_{1} \simeq \mathbb {Z}_{p}^{\times }$ be a normal subgroup of finite index, such that $U \simeq \mathbb {Z}_{p}$ . As finite groups have no rational cohomology, Lyndon–Hochschild–Serre spectral sequence collapses and gives an isomorphism

$$\begin{align*}\mathrm{H}^{i}(\mathbb{G}_{1}, \mathbb{Q}_{p}(k)) \simeq \mathrm{H}^{i}(U, \mathbb{Q}_{p}(k))^{\mathbb{G}_{1}/U}. \end{align*}$$

It follows that the cohomology groups vanish above degree $1$ , as $U \simeq \mathbb {Z}_{p}$ is of cohomological dimension one.

As $U \simeq \mathbb {Z}_{p}$ is cyclic as a profinite group, its cohomology can be computed using a two-step cochain complex, as we did in Section 10. It follows that the only one-dimensional representation of U over $\mathbb {Q}_{p}$ with nontrivial cohomology is the trivial one. As the characters $\mathbb {Q}_{p}(k)$ restrict to nontrivial representations for $k \neq 0$ , we deduce that

$$\begin{align*}\mathrm{H}^{1}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{Q}_{p}[b^{\pm 1}]) \simeq \mathrm{H}^{1}_{\operatorname{\mathrm{cts}}}(\mathbb{G}_{1}, \mathbb{Q}_{p}) \simeq \mathbb{Q}_{p} \end{align*}$$

as claimed.

Theorem 15.12. At height $n=1$ and any prime, we have

$$\begin{align*}\mathrm{H}_{\operatorname{\mathrm{cts}}}^{s}(\mathbb{G}_{1}, E_{*}E) \simeq \begin{cases} E_{*} \otimes_{\mathbb{Z}} \mathbb{Z}_{p} & \mbox{when } s=0;\\ E_{*} \otimes_{\mathbb{Z}} \mathbb{Q}_{p}& \mbox{when } s=1;\\ 0 & \mbox{otherwise}. \end{cases} \end{align*}$$

Proof. As we observed previously that the cohomology with coefficients in $E_{*}E$ is concentrated in even internal degrees and $2$ -periodic, it is enough to establish this in internal degree zero, where this is a combination of Corollary 15.4 and Propositions 15.9 and 15.11.

Remark 15.13. As we observed at the beginning, the cohomology groups of Theorem 15.12 coincide with derived functors of completion in comodules by Proposition 12.12. Using the latter perspective, a sketch of the calculation of the rationalisation of the above groups at $p> 2$ appears in a talk by Hopkins, recorded in [Reference PetersonPet, Talk 14]. We were independently informed by Hopkins that he first made this calculation in the 1990s and that it was part of the motivation towards the algebraic chromatic splitting conjecture.

Acknowledgments

We would like to thank Agnès Beaudry, Robert Burklund, Mike Hopkins, Eric Peterson and Hal Sadofsky for useful conversations related to this work. We acknowledge the hospitality of the Max Planck Institute for Mathematics in Bonn.

Competing Interest

None.

Footnotes

1 A common saying about the classical Adams spectral sequence is ‘Every differential is a theorem’.

2 The construction of Hopkins and Sadofsky is unpublished.

3 We note that the statement given there contains a typo: the left-hand side of the equation should have $v_{n-1}$ inverted.

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