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Distal systems in topological dynamics and ergodic theory

Published online by Cambridge University Press:  01 August 2022

NIKOLAI EDEKO
Affiliation:
Institut für Mathematik, Universität Zürich, Winterthurerstrasse 190, CH-8057 Zürich, Switzerland (e-mail: [email protected])
HENRIK KREIDLER*
Affiliation:
Fachgruppe für Mathematik und Informatik, Bergische Universität Wuppertal, Gaußstraße 20, D-42119 Wuppertal, Germany
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Abstract

We generalize a result of Lindenstrauss on the interplay between measurable and topological dynamics which shows that every separable ergodic measurably distal dynamical system has a minimal distal model. We show that such a model can, in fact, be chosen completely canonically. The construction is performed by going through the Furstenberg–Zimmer tower of a measurably distal system and showing that at each step there is a simple and canonical distal minimal model. This hinges on a new characterization of isometric extensions in topological dynamics.

Type
Original Article
Copyright
© The Author(s), 2022. Published by Cambridge University Press

1 Introduction

The famous Furstenberg structure theorem shows that every distal minimal topological dynamical system can be built from a trivial system only by successively performing ‘structured’ (that is, (pseudo)isometric) extensions; see, for example, [Reference FurstenbergFur63] and [Reference de VriesdV93, §V.3]. As shown by Zimmer (see [Reference ZimmerZim76, Theorem 8.7]), this classical result has an analogue for distal systems in ergodic theory introduced earlier by Parry in [Reference Parry, Auslander and GottschalkPar68]: a measure-preserving system on a standard probability space is distal if and only if it can be constructed from a tower of measure-theoretically isometric extensions. The significance of these measurably distal systems is due to the fact that—by the Furstenberg–Zimmer structure theorem—any measure-preserving system can be recovered by taking a weakly mixing extension of a distal one (see, for example, [Reference FurstenbergFur77], [Reference TaoTao09, Ch. 2] or [Reference Edeko, Haase and KreidlerEHK21]). This allows one to reduce the proof of important results for measure-preserving transformations, such as Furstenberg’s recurrence result used for an ergodic-theoretic proof of Szemerédi’s theorem, to the case of distal systems.

Given a minimal distal system $(K;\varphi )$ and an ergodic $\varphi $ -invariant probability measure $\mu $ on K, it is not hard to prove that $(K, \mu; \varphi )$ is also distal as a measure-preserving system. While this has long been known, the converse question, whether a distal measure-preserving system admits a distal topological model, was only answered much later in an paper by Lindenstrauss (see [Reference LindenstraussLin99] and also [Reference Glasner, Weiss, Hasselblatt and KatokGW06, §§5 and 13]).

Theorem. Every ergodic distal measure-preserving system on a standard probability space has a minimal distal metrizable topological model.

Topological models such as these continue to prove useful since they allow us to use a range of topological results to derive results in ergodic theory. For recent examples, we refer to the proof of pointwise convergence for multiple averages for distal systems (see [Reference Huang, Shao and XiangdongHSX19]), new approaches to the Furstenberg–Zimmer structure theorem (see [Reference Edeko, Haase and KreidlerEHK21, §7.4]), and a new approach to the Host–Kra factors in [Reference Gutman and LianGL19].

Lindenstrauss’s proof rests on the Mackey–Zimmer representation of isometric extensions as skew-products and on measure-theoretic considerations. In this paper we pursue an operator-theoretic approach to the result and even prove that for every ergodic distal system there is a canonical minimal distal topological model. This allows to construct such models in a functorial way: every extension between ergodic distal systems induces a topological extension between their canonical models.

The key step is to show that an isometric extension of measure-preserving systems admits a completely canonical topological model that is a (pseudo)isometric extension of topological dynamical systems. The proof of this requires a new functional-analytic characterization of structured extensions in topological dynamics as established in [Reference Edeko and KreidlerEK21], related results from ergodic theory (see [Reference Edeko, Haase and KreidlerEHK21]), as well as a result of Derrien on approximation of measurable cocycles by continuous ones (see [Reference DerrienDer00]). The functional-analytic view makes the parallels between the structure theory of topological and measure-preserving dynamical systems more apparent and leads to canonical models in a straightforward way. In addition, our methods allow us to generalize Lindenstrauss’s result to measure-preserving transformations on arbitrary probability spaces, following up on a recent endeavor to drop separability assumptions from classical results of ergodic theory (see [Reference Edeko, Haase and KreidlerEHK21, Reference Jamneshan and TaoJT20]).

Organization of the paper. We start in §2 with the concepts of structured extensions of topological dynamical systems. Then, based on the results of [Reference Edeko and KreidlerEK21], we prove an operator-theoretic characterization of (pseudo)isometric extensions in terms of the Koopman operator (see Theorem 2.8). In §3 we consider structured extensions in ergodic theory, that is, extensions with relative discrete spectrum, and recall an important characterization from [Reference Edeko, Haase and KreidlerEHK21] (see Proposition 3.8). The major work is done in §4 where we construct topological models for structured extensions of measure-preserving systems (see Theorem 4.6). This result is applied in the final section of the paper to show that every ergodic distal measure-preserving system has a minimal distal topological model (see Theorem 5.9). Finally, we discuss the meaning of our result in a category-theoretical sense in Remark 5.11.

Preliminaries and notation. We now set up the notation and recall some important concepts from topological dynamics and ergodic theory. The monograph [Reference Eisner, Farkas, Haase and NagelEFHN15] serves as a general reference for the operator-theoretic approach followed in this paper.

In the following all vector spaces are complex and all compact spaces are assumed to be Hausdorff. If E and F are Banach spaces, then $\mathscr {L}(E,F)$ denotes the space of all bounded linear operators from E to F. We write $\mathscr {L}(E) := \mathscr {L}(E,E)$ and $E' := \mathscr {L}(E,{\mathbb {C}})$ . If $T \in \mathscr {L}(E,F)$ is a bounded operator, then $T' \in \mathscr {L}(F',E')$ denotes its adjoint.

Given a compact space K, we write $\mathcal {U}_K$ for the unique uniformity compatible with the topology of K. Moreover, $\mathrm {C}(K)$ denotes the space of all continuous complex-valued functions which is a unital commutative $\mathrm {C}^*$ -algebra (cf. [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 4]). Using the Markov–Riesz representation theorem (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Appendix E]), we identify its dual space $\mathrm {C}(K)'$ with the space of all complex regular Borel measures on K. Likewise, if ${\mathrm {X}} = (X, \Sigma , \mu )$ is a probability space, then we write $\mathrm {L}^p({\mathrm {X}})$ with $1 \leqslant p \leqslant \infty $ for the associated complex $\mathrm {L}^p$ -spaces and identify the dual $\mathrm {L}^1({\mathrm {X}})'$ with $\mathrm {L}^\infty ({\mathrm {X}})$ .

A topological dynamical system $(K;\varphi )$ consists of a compact space K and a homeomorphism $\varphi : K \rightarrow K$ . It is minimal if there are non-trivial closed subsets $M \subseteq K$ with $\varphi (M) = M$ . Moreover, we call $(K;\varphi )$ metrizable if the underlying compact space K is metrizable. We refer to [Reference AuslanderAus88] for a general introduction to such systems. Topological dynamical systems can be studied effectively via operator theory by considering the induced Koopman operator $T_\varphi \in \mathscr {L}(\mathrm {C}(K))$ defined by $T_\varphi f := f \circ \varphi $ for $f \in \mathrm {C}(K)$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 4]). We remind the reader that $T_\varphi $ is a *-automorphism of the $\mathrm {C}^*$ -algebra $\mathrm {C}(K)$ . In fact, every *-automorphism of $\mathrm {C}(K)$ is a Koopman operator associated to a uniquely determined homeomorphism of K (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 4.13]). We write $\mathrm {P}_{\varphi }(K) \subseteq \mathrm {C}(K)'$ for the space of all invariant probability measures $\mu $ on K, that is, $T_\varphi '\mu = \mu $ . Moreover, ${\operatorname {supp}}\ \mu $ denotes the support of such a measure (see [Reference Eisner, Farkas, Haase and NagelEFHN15, pp. 82]), and we say that $\mu $ is fully supported if ${\operatorname {supp}}\ \mu = K$ . Moreover, we write $(K,\mu )$ for the induced probability space.

Classically, a measure-preserving point transformation is a pair $({\mathrm {X}};\varphi )$ of a probability space ${\mathrm {X}} = (X,\Sigma _X,\mu _X)$ and a measurable and measure-preserving map $\varphi : {\mathrm {X}} \rightarrow {\mathrm {X}}$ which is essentially invertible, that is, there is a map $\psi : {\mathrm {X}} \rightarrow {\mathrm {X}}$ such that $\psi \circ \varphi = \mathrm {id}_X = \varphi ~\circ ~\psi $ almost everywhere. We refer to [Reference Einsiedler and WardEW11, Gla03] for an introduction. Given any measure-preserving point transformation $({\mathrm {X}};\varphi )$ , we define the Koopman operator on the corresponding $\mathrm {L}^1$ -space via $T_\varphi f := f \circ \varphi $ for $f \in \mathrm {L}^1({\mathrm {X}})$ . These operators are so-called Markov lattice isomorphisms on the Banach lattice $\mathrm {L}^1({\mathrm {X}})$ , that is, invertible isometries $T \in \mathscr {L}(\mathrm {L}^1({\mathrm {X}}))$ satisfying:

  • $\lvert Tf\rvert = T\lvert f \rvert $ for every $f \in \mathrm {L}^1({\mathrm {X}})$ , and

  • .

We refer to [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 13] for more information on such operators. If ${\mathrm {X}}$ is a standard probability space (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Definition 6.8]), then a result of von Neumann shows that every Markov lattice isomorphism $T \in \mathscr {L}(\mathrm {L}^1({\mathrm {X}}))$ is a Koopman operator of a measure-preserving point transformation (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Proposition 7.19 and Theorem 7.20]). For a general probability space ${\mathrm {X}}$ one can only show that such operators are induced by transformations of the measure algebra of ${\mathrm {X}}$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 12.10]). Here, we avoid these measure-theoretic intricacies by defining a measure-preserving system in terms of operators theory. A measure-preserving system is a pair $({\mathrm {X}};T)$ of a probability space ${\mathrm {X}}$ and a Markov lattice isomorphism $T \in \mathscr {L}(\mathrm {L}^1({\mathrm {X}}))$ (cf. [Reference Eisner, Farkas, Haase and NagelEFHN15, Definition 12.18]). It is ergodic if the fixed space

$$ \begin{align*} {\operatorname{fix}}(T) := \{f \in \mathrm{L}^1(X)\mid Tf = f\} \end{align*} $$

is one-dimensional (cf. [Reference Eisner, Farkas, Haase and NagelEFHN15, Proposition 7.15]). We say that $({\mathrm {X}};T)$ is separable if the measure space ${\mathrm {X}}$ is separable, or equivalently, if the Banach space $\mathrm {L}^1({\mathrm {X}})$ is separable.

2 Structured extensions in topological dynamics

In order to state and prove one of our main results, Theorem 4.6, we need to briefly recap the notions of structured extensions in topological dynamics and ergodic theory together with their different characterizations. So we start with the notion of (pseudo)isometric extensions of topological dynamical systems and their functional-analytic characterization in Theorem 2.8.

Definition 2.1. An extension $q : (K;\varphi ) \rightarrow (L;\psi )$ between topological dynamical systems $(K;\varphi )$ and $(L;\psi )$ is a continuous surjection $q : K \rightarrow L$ such that the diagram

commutes. In this case, we call $(L;\psi )$ a factor of $(K;\varphi )$ . We write $K_l := q^{-1}(l)$ for the fiber of K over $l \in L$ and define the fiber product $K \times _L K$ of K over L as

$$ \begin{align*} K \times_L K := \bigcup_{l \in L} K_l \times K_l \subseteq K \times K. \end{align*} $$

Remark 2.2. There is an equivalent functional-analytic perspective on extensions based on Gelfand duality. Let $(K;\varphi )$ be a topological dynamical system and call a subset $M \subseteq \mathrm {C}(K)$ invariant if $T_\varphi M = M$ . If $q : (K;\varphi ) \rightarrow (L;\psi )$ is an extension, then $T_q : \mathrm {C}(L) \rightarrow \mathrm {C}(K), f\ {\mapsto} f \circ q$ is an isometric *-homomorphism intertwining the Koopman operators. Therefore, $A_q := T_q(\mathrm {C}(L)) \subseteq \mathrm {C}(K)$ is an invariant unital $\mathrm {C}^*$ -subalgebra of $\mathrm {C}(K)$ . On the other hand, if $A \subseteq \mathrm {C}(K)$ is such an invariant unital $\mathrm {C}^*$ -subalgebra, then $T_\varphi $ induces a homeomorphism $\psi $ on the Gelfand space L of A and the embedding $A \hookrightarrow \mathrm {C}(K)$ gives rise to an extension $q : (K;\varphi ) \rightarrow (L;\psi )$ with $A = A_q$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 4]). Thus, instead of looking at factors of a given system $(K;\varphi )$ , one can also examine the invariant unital $\mathrm {C}^*$ -subalgebras of $\mathrm {C}(K)$ .

We now look at structured extensions of topological dynamical systems. There are basically two ways to start from the notion of an isometric or equicontinuous system and relativize it to extensions: one is based on the existence of invariant (pseudo)metrics, while the other generalizes the concept of equicontinuity (cf. [Reference de VriesdV93, §§V.2 and V.5] and [Reference Edeko and KreidlerEK21, Definition 1.15]).

Definition 2.3. An extension $q : (K;\varphi ) \rightarrow (L;\psi )$ of topological dynamical systems is called:

  1. (i) pseudoisometric if there is a family P of continuous mappings

    $$ \begin{align*} p : K \times_L K \rightarrow {\mathbb{R}}_{\geqslant 0} \end{align*} $$
    such that:
    • $p|_{K_l \times K_l}$ is a pseudometric on $K_l$ for every $l \in L$ and $p \in P$ ,

    • $\{p|_{K_l \times K_l}\mid l \in L\}$ generates the topology on $K_l$ for every $l \in L$ , and

    • $p(\varphi (x),\varphi (y)) = p(x,y)$ for all $(x,y) \in K\times _L K$ and $p \in P$ ;

  2. (ii) isometric if it is pseudoisometric and P in (i) can be chosen to only have one element (which then defines a metric on every fiber);

  3. (iii) equicontinuous if for every entourage $V \in \mathcal {U}_K$ there is an entourage $U \in \mathcal {U}_K$ such that for every pair $(x,y) \in K \times _L K$

    $$ \begin{align*} (x,y) \in U \, \Rightarrow \, (\varphi^k(x),\varphi^k(y)) \in V\quad \text{for every } k \in {\mathbb{Z}}. \end{align*} $$

Remark 2.4. Every pseudoisometric extension is equicontinuous by [Reference Edeko and KreidlerEK21, Proposition 1.17], while the converse may fail (see [Reference Edeko and KreidlerEK21, Example 3.15]). However, if $(K;\varphi )$ (and hence also $(L;\psi )$ ) is minimal, then the two notions coincide (see [Reference de VriesdV93, Corollary 5.10]).

The following is a standard example of an isometric extension.

Example 2.5. (Skew-rotation)

Let ${\mathbb {T}} := \{x \in {\mathbb {C}} \mid \lvert x \rvert = 1\}$ and $a \in {\mathbb {T}}$ . We consider $(K;\varphi )$ defined by $K:= {\mathbb {T}}^2$ with $\varphi (x,y) := (ax,xy)$ for $(x,y) \in K$ , and $(L;\psi )$ given by $L := {\mathbb {T}}$ with $\psi (x) = ax$ for $x \in L$ . Then the projection $q : {\mathbb {T}}^2 \rightarrow {\mathbb {T}}$ onto the first component defines an isometric extension $q: (K;\varphi ) \rightarrow (L;\psi )$ .

Recall that a system $(K;\varphi )$ is equicontinuous (see [Reference AuslanderAus88, Ch. 2]) if and only if the induced Koopman operator $T_\varphi \in \mathscr {L}(\mathrm {C}(K))$ has discrete spectrum, that is, $\mathrm {C}(K)$ is the closed linear hull of all eigenspaces of the Koopman operator (see, for example, [Reference EdekoEde19, Proposition 1.6]). Is there a more general version of this that can be used to characterize when an extension $q: (K; \varphi ) \to (L; \psi )$ is pseudoisometric? If $(L; \psi )$ satisfies a mild irreducibility condition, Theorem 2.8 below provides an affirmative answer. To state it, we require the definition of topological ergodicity (analogous to ergodicity) and we need to recall the module structure an extension gives rise to.

Definition 2.6. A topological dynamical system $(K;\varphi )$ is topologically ergodic if the fixed space

$$ \begin{align*} {\operatorname{fix}}(T_\varphi) := \{f \in \mathrm{C}(K) \mid T_\varphi f = f\} \end{align*} $$

of the Koopman operator $T_\varphi \in \mathscr {L}(\mathrm {C}(K))$ is one-dimensional.

Every minimal system is topologically ergodic, but the class of topologically ergodic systems is considerably larger and contains, for example, all topologically transitive systems.

Remark 2.7. One of the key tools in the study of extensions of dynamical systems is the module structure that canonically emerges from an extension and is often tacitly used. Let $q : K \rightarrow L$ be a continuous surjection between compact spaces and $T_q : \mathrm {C}(L) \rightarrow \mathrm {C}(K), \, f \mapsto f \circ q$ the induced isometric $^*$ -homomorphism. Via this embedding we can define a multiplication

$$ \begin{align*} \mathrm{C}(L) \times \mathrm{C}(K) \rightarrow \mathrm{C}(K), \quad (f,g) \mapsto T_qf \cdot g \end{align*} $$

that turns $\mathrm {C}(K)$ into a $\mathrm {C}(L)$ -module in a canonical way.

We now obtain the following operator-theoretic characterization of pseudoisometric extensions in terms of a relative notion of discrete spectrum. Recall here that a module M over a unital commutative ring R is projective if there is another module N over R such that the direct sum $M \oplus N$ is free, that is, has a basis.

Theorem 2.8. Let $q : (K;\varphi ) \rightarrow (L;\psi )$ be an extension of topological dynamical systems. Assume that $(L;\psi )$ is topologically ergodic and q is open. Then the following assertions are equivalent.

  1. (a) q is pseudoisometric.

  2. (b) The union of all closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules is dense in $\mathrm {C}(K)$ .

  3. (c) The unital $\mathrm {C}^*$ -algebra generated by all closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules is the whole space $\mathrm {C}(K)$ .

If K is even metrizable, then (a) can be replaced by

  • (a′) q is isometric.

If $(L;\psi )$ is minimal, the assumption that q is open can be dropped.

Remark 2.9. Loosely speaking, assertions (b) and (c) of Theorem 2.8 mean that $\mathrm {C}(K)$ is generated by invariant parts which are ‘small’ relative to $\mathrm {C}(L)$ .

We remark that, except for the last statement about minimal $(L; \psi )$ , Theorem 2.8 is a special case of [Reference Edeko and KreidlerEK21, Theorem 7.2]. Thus, we only need to prove this additional statement. To do this, we show that, in case of a minimal system $(L;\psi )$ , each of the assertions (a) and (c) (and consequently also the stronger conditions (b) and (a $^\prime $ )) imply that q is open.

We start by proving that (a) yields that the extension is open. In fact, this implication is valid for the more general class of distal extensions (cf. [Reference BronšteǐnBro79, §3.12]).

Definition 2.10. An extension $q: (K;\varphi ) \rightarrow (L;\psi )$ is distal if the following condition is satisfied: whenever $(x,y) \in K \times _L K$ and $(\varphi ^{n_\alpha })_{\alpha \in A}$ is a net with $n_\alpha \in {\mathbb {Z}}$ for $\alpha \in A$ and $\lim _\alpha \varphi ^{n_\alpha }(x) = \lim _\alpha \varphi ^{n_\alpha }(y)$ , then $x=y$ .

Lemma 2.11. Let $q : (K,\varphi ) \rightarrow (L,\psi )$ be a distal extension of topological dynamical systems with $(L,\psi )$ minimal. Then q is open.

The result is stated as a remark in [Reference Auslander and AssaniAus13, p. 2] without proof. Since we have found a proof in the literature only for the case of minimal $(K;\varphi )$ , we provide a proof of Lemma 2.11 based on the arguments of [Reference BronšteǐnBro79, Lemma 3.14.5] and [Reference AuslanderAus88, Theorem 10.8].

Proof of Lemma 2.11

Consider the Ellis semigroup of the system $(K;\varphi )$ given by

$$ \begin{align*} \mathrm{E}(K;\varphi) := \overline{\{\varphi^n \mid n \in {\mathbb{Z}} \}} \subseteq K^K \end{align*} $$

where the closure is taken with respect to the topology of pointwise convergence (see [Reference AuslanderAus88, Ch. 3]). For every $l \in L$ the set

$$ \begin{align*} E_l := \{\vartheta : K_l \rightarrow K_l \mid\text{there exists } \tau \in \mathrm{E}(K;\varphi) \textrm{ with } \vartheta = \tau|_{K_l}\} \subseteq K_l^{K_l}, \end{align*} $$

equipped with composition of mappings and the product topology, is a compact right-topological semigroup (see [Reference Berglund, Junghenn and MilnesBJM89, §1.3] or [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 16] for this concept). As a preliminary step, we show that these are actually groups. To this end, we recall from the structure theory of compact right-topological semigroups that every such semigroup contains at least one idempotent and is a group if and only if it has a unique idempotent (see [Reference Berglund, Junghenn and MilnesBJM89, Theorems 2.12 and 3.11]).

Now take $l \in L$ and an idempotent $\vartheta \in E_l$ (that is, $\vartheta ^2 = \vartheta $ ). For $x \in K_l$ consider $y := \vartheta (x) \in K_l$ . Then $\vartheta (y) = \vartheta ^2(x) = \vartheta (x)$ , which implies $x = y$ since q is distal. Therefore, $\mathrm {id}_{K_l}$ is the only idempotent in $E_l$ and thus $E_l$ is in fact a group.

We now prove that q is open. Take an $x \in K$ and let $l := q(x)$ . Assume that $(l_\alpha )_{\alpha \in A}$ is a net in L converging to l. It suffices to show that there is a subnet $(l_\beta )_{\beta \in B}$ of $(l_\alpha )_{\alpha \in A}$ and $x_\beta \in K_{l_\beta }$ for every $\beta \in B$ such that $\lim _{\beta } x_\beta = x$ . We recall that, since $(L;\psi )$ is minimal, for every $\alpha \in A$ ,

$$ \begin{align*} \mathrm{E}(L;\psi)(l_\alpha) = \overline{ \{\varphi^n(l_\alpha)\mid n \in {\mathbb{Z}}\}} = L. \end{align*} $$

Moreover,

$$ \begin{align*} \mathrm{E}(K;\varphi) \rightarrow \mathrm{E}(L;\psi), \quad \tau \mapsto [q(y) \mapsto q(\tau(y))] \end{align*} $$

is a surjective homomorphism of compact right-topological semigroups by [Reference AuslanderAus88, Theorem 3.7]. With these two observations we find $\tau _\alpha \in \mathrm {E}(K,\varphi )$ with $q(\tau _\alpha (x)) = l_\alpha $ for every $\alpha \in A$ . Passing to a subnet, we may assume that $(\tau _\alpha )_{\alpha \in A}$ converges to some $\tau \in \mathrm {E}(K;\varphi )$ . Moreover, $\tau (x) = \lim _{\alpha } \tau _\alpha (x) \in K_l$ , which already implies $\tau (K_l) \subseteq K_l$ (see [Reference BronšteǐnBro79, Lemma 3.12.10]), that is, $\vartheta := \tau |_{K_l} \in E_l$ . But then converges to x and $x_\alpha \in K_{l_\alpha }$ for every $\alpha \in A$ .

Since equicontinuous (and, in particular, pseudoisometric) extensions are distal (see [Reference BronšteǐnBro79, Lemma 3.12.5]), we now obtain that assertion (a) of Theorem 2.8 implies that the extension is open if $(L;\psi )$ is minimal. The following result combined with Lemma 2.11 shows that, for minimal $(L;\psi )$ , (c) also implies openness, which proves Theorem 2.8. In the proof, we will use the canonical correspondence between Banach bundles and Banach modules; the reader can find a self-contained summary of the essentials in [Reference Edeko and KreidlerEK21, §4].

Lemma 2.12. Let $q : (K,\varphi ) \rightarrow (L,\psi )$ be an extension. Suppose that the $\mathrm {C}^*$ -algebra generated by all closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules is the whole space $\mathrm {C}(K)$ . Then q is equicontinuous.

Proof. The uniformity on K is generated by the sets $U_{f, \varepsilon }$ which, for $f \in \mathrm {C}(K)$ and $\varepsilon>0$ , are defined as

Our assumption therefore yields that q is equicontinuous if and only if the assertion following holds. For every ${\mathrm {C}}(L)$ -submodule $M \subseteq \mathrm {C}(K)$ that is closed, invariant, finitely generated, and projective, for every $f \in M$ and every $\varepsilon> 0$ , we find an entourage $U \in \mathcal {U}_K$ such that

$$ \begin{align*} \text{ for all } (x,y) \in K \times_L K: (x,y) \in U \, \Rightarrow \, \lvert f(\varphi^k(x)) -f(\varphi^k(y))\rvert < \varepsilon \quad \textrm{for all } k \in {\mathbb{Z}}. \end{align*} $$

It suffices to show the claim only for $f \in M$ with $\lVert f\rVert \leqslant 1$ . By looking at finitely many generators for M, we will in fact be able to show that the uniformity U can be chosen uniformly for all $f\in M$ with $\lVert f\rVert \leqslant 1$ . We will do so by constructing a continuous pseudometric $p: K \times K \to {\mathbb {R}}_{\geqslant 0}$ from M such that

$$ \begin{align*} \text{ for all } f\in M\cap \overline{\mathrm{B}_1(0)}, \text{ for all } x, y\in K : \lvert f(x) - f(y)\rvert \leqslant p(x, y). \end{align*} $$

The desired uniformity is then given by $U = \{ (x,y)\in K\times K \mid p(x, y) < \varepsilon \}$ . To do this, we exploit the fact that there is a one-to-one correspondence between projective, finitely generated ${\mathrm {C}}(L)$ -modules and locally trivial vector bundles over L: by [Reference GierzGie82, Theorem 8.6 and Remark 8.7] and [Reference Edeko and KreidlerEK21, Example 4.5], the vector spaces

$$ \begin{align*} M_l := \{f|_{K_l} \mid l \in L\} \subseteq \mathrm{C}(K_l) \end{align*} $$

for $l \in L$ define a Banach bundle over L (see [Reference GierzGie82] or [Reference Dupré and GilletteDG83] for this concept). This is locally trivial by [Reference Edeko and KreidlerEK21, Lemma 4.13], which—using [Reference GierzGie82, Proposition 17.2 and Corollary 4.5]—can be characterized in the following way.

  • There are closed subsets $L_1,\ldots , L_m \subseteq L$ with $L = \bigcup _{j=1}^m L_j$ .

  • For every $n \in \{1, \ldots ,m\}$ there are $s_{n,1}, \ldots , s_{n,k_n}\in M$ such that

    $$ \begin{align*} \Phi_n : \mathrm{C}(L_n)^{k_n} \rightarrow M|_{q^{-1}(L)}, \quad (f_1, \ldots, f_{k_n}) \mapsto \sum_{j=1}^{k_n} f_j s_{n,j}|_{q^{-1}(L_n)} \end{align*} $$
    is a $\mathrm {C}(L_n)$ -linear (not necessarily isometric) isomorphism between the product Banach space $\mathrm {C}(L_n)^{k_n}$ with the maximum norm and the subspace $M|_{q^{-1}(L_n)} \subseteq \mathrm {C}(q^{-1}(L_n))$ .

For every $n \in \{1, \ldots , m\}$ we now consider the continuous seminorm

$$ \begin{align*} p_n : K \times K \rightarrow {\mathbb{R}}_{\geqslant 0}, \quad (x,y) \mapsto \sum_{j=1}^{k_n} \lvert s_{n,j}(x)-s_{n,j}(y)\rvert \end{align*} $$

and show that there is a constant $C> 0$ such that

$$ \begin{align*} \lvert f(x)- f(y)\rvert \leqslant C \cdot \max_{n=1,\ldots,m} p_n(x,y) \end{align*} $$

for all $(x,y) \in K \times _L K$ and $f \in M$ with $\lVert f\rVert \leqslant 1$ . This will finish the proof.

It suffices to show that for every $n \in \{1, \ldots ,m\}$ there is a constant $C_n> 0$ such that the inequality

$$ \begin{align*} \lvert f(x)- f(y)\lvert \leqslant C_n \cdot p_n(x,y) \end{align*} $$

holds for every pair $(x,y) \in K \times _L K$ with $q(x) = q(y) \in L_n$ , and every $f \in M$ with $\lVert f\rVert \leqslant ~1$ . We fix $n \in \{1, \ldots ,m\}$ and set $C_n := \lVert \Phi _n^{-1}\rVert>0$ . For $(x,y) \in K \times _L K$ with $l := q(x) = q(y) \in L_n$ we then obtain, for all $f_1, \ldots , f_{k_n} \in {\mathrm {C}}(L_n)$ ,

$$ \begin{align*} |\Phi(f_1, \ldots, f_{k_n})(x) - \Phi(f_1, \ldots, f_{k_n})(y)| &\leqslant \sum_{j=1}^{k_n} \lvert f_{j}(l)(s_{n,j}(x)-s_{n,j}(y))\rvert \\ &\leqslant \lVert (f_1, \ldots, f_{k_n})\rVert \cdot p_n(x,y). \end{align*} $$

Since $\Phi _n$ is an isomorphism, we conclude that

$$ \begin{align*} \lvert f(x) - f(y)\rvert \leqslant C_n \cdot p_n(x,y) \end{align*} $$

for every pair $(x,y) \in K \times _L K$ with $q(x) = q(y) \in L_n$ , and every $f \in M$ with $\lVert f\rVert \leqslant 1$ . This is the desired inequality.

3 Structured extensions in ergodic theory

We now turn to structured extensions of measure-preserving systems. In our operator-theoretic language the following is the natural definition of an extension in ergodic theory. Recall here that if ${\mathrm {X}}$ and ${\mathrm {Y}}$ are probability spaces, then an isometry $J \in \mathscr {L}(\mathrm {L}^1({\mathrm {Y}}),\mathrm {L}^1({\mathrm {X}}))$ is a Markov embedding (or Markov lattice homomorphism) if:

  • $\lvert Jf\rvert = J\lvert f\rvert $ for every $f \in \mathrm {L}^1({\mathrm {Y}})$ ;

  • .

Definition 3.1. An extension (or morphism) $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ of measure-preserving systems is a Markov embedding $J \in \mathscr {L}(\mathrm {L}^1({\mathrm {Y}}), \mathrm {L}^1({\mathrm {X}}))$ such that the diagram

commutes. If J is also bijective, then it is an isomorphism of measure-preserving systems.

Remark 3.2. Given any Markov lattice homomorphism $J \in \mathscr {L}(\mathrm {L}^1({\mathrm {Y}}),\mathrm {L}^1({\mathrm {X}}))$ for probability spaces ${\mathrm {X}}$ and ${\mathrm {Y}}$ , the adjoint $J' \in \mathscr {L}(\mathrm {L}^\infty ({\mathrm {X}}),\mathrm {L}^\infty ({\mathrm {Y}}))$ extends uniquely to a bounded positive operator $\mathbb {E}_{{\mathrm {Y}}} \in \mathscr {L}(\mathrm {L}^1({\mathrm {X}}),\mathrm {L}^1({\mathrm {Y}}))$ satisfying $\mathbb {E}_{{\mathrm {Y}}}((Jf) \cdot g) = f \cdot \mathbb {E}_{{\mathrm {Y}}}(g)$ for all $f \in \mathrm {L}^\infty ({\mathrm {Y}})$ and $g \in \mathrm {L}^1({\mathrm {X}})$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, §13.3]). We call $\mathbb {E}_{{\mathrm {Y}}}$ the conditional expectation operator associated with J. If J is an extension of measure-preserving systems, then $\mathbb {E}_{{\mathrm {Y}}}$ intertwines the dynamics.

Remark 3.3. As in the topological setting, we obtain a canonical module structure (cf. Remark 2.7). Indeed, if $f_1,f_2 \in \mathrm {L}^\infty ({\mathrm {Y}})$ , then $J(f_1\cdot f_2) = J(f_1) \cdot J(f_2)$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, §13.2]) and this implies that the multiplication

$$ \begin{align*} \mathrm{L}^\infty({\mathrm{Y}}) \times \mathrm{L}^1({\mathrm{X}}) \rightarrow \mathrm{L}^1({\mathrm{X}}), \quad (f,g) \mapsto J(f)\cdot g \end{align*} $$

turns $\mathrm {L}^1({\mathrm {X}})$ into a module over $\mathrm {L}^\infty ({\mathrm {Y}})$ . For every $p \in [1,\infty ]$ the space $\mathrm {L}^p({\mathrm {X}})$ is a $\mathrm {L}^\infty ({\mathrm {X}})$ -submodule of $\mathrm {L}^1({\mathrm {X}})$ .

As in topological dynamics, there are several notions of ‘structured extensions’ in ergodic theory. We use the following one, implicitly used by Ellis in [Reference EllisEll87] and inspired by the classical notion of discrete spectrum for measure-preserving systems. Here, as above, a subset $M \subseteq \mathrm {L}^1({\mathrm {X}})$ is invariant if $T(M) = M$ .

Definition 3.4. An extension $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ of measure-preserving systems has relative discrete spectrum if the union of all finitely generated invariant submodules of $\mathrm {L}^\infty ({\mathrm {X}})$ over $\mathrm {L}^\infty ({\mathrm {Y}})$ is dense in $\mathrm {L}^1({\mathrm {X}})$ .

Example 3.5. Consider the skew-rotation $q : (K; \varphi ) \rightarrow (L;\psi )$ of Example 2.5. By equipping the torus $L = {\mathbb {T}}$ with the Haar measure $\nu $ and its product $K = {\mathbb {T}}^2$ with the product measure $\mu = \nu \times \nu $ , we arrive at an extension $(L,\nu ;T_\psi ) \rightarrow (K,\mu ;T_\varphi )$ of measure-preserving systems which has relative discrete spectrum (see [Reference Edeko, Haase and KreidlerEHK21, Example 6.12]). More generally, homogenous skew-products are prototypical examples of extensions with relative discrete spectrum (see, for example, [Reference ZimmerZim76] and [Reference EllisEll87, §§4 and 5]).

Equivalent definitions of relative discrete spectrum are listed in [Reference Edeko, Haase and KreidlerEHK21, Proposition 6.13]. We need one using modules with an orthonormal basis which uses the idea that

$$ \begin{align*} \mathrm{L}^\infty({\mathrm{X}}) \times \mathrm{L}^\infty({\mathrm{X}}) \rightarrow \mathrm{L}^\infty({\mathrm{Y}}), \quad (f,g) \mapsto \mathbb{E}_{{\mathrm{Y}}}(f\overline{g}) \end{align*} $$

can be thought of as an $\mathrm {L}^\infty ({\mathrm {Y}})$ -valued inner product. We refer to [Reference Edeko, Haase and KreidlerEHK21] for a systematic approach to this idea in terms of Hilbert modules.

Definition 3.6. Let $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ be an extension of measure-preserving systems. A finite subset $\{e_1, \ldots , e_n\} \subseteq \mathrm {L}^\infty ({\mathrm {X}})$ is ${\mathrm {Y}}$ -orthonormal if for $i,j \in \{1, \ldots ,n\}$ . In this case we say that $e_1, \ldots , e_n$ is a ${\mathrm {Y}}$ -orthonormal basis of the $\mathrm {L}^\infty ({\mathrm {Y}})$ -module generated by $e_1, \ldots , e_n$ .

Remark 3.7. If $\{e_1, \ldots , e_n\} \subseteq \mathrm {L}^\infty ({\mathrm {X}})$ is a ${\mathrm {Y}}$ -orthonormal basis of an $\mathrm {L}^\infty ({\mathrm {Y}})$ -submodule M as in Definition 3.6, then every $f \in M$ can be written as

$$ \begin{align*} f = \sum_{j=1}^n \mathbb{E}_{{\mathrm{Y}}}(f \cdot \overline{e_j}) e_j. \end{align*} $$

With this observation it is readily checked that any submodule $M \subseteq \mathrm {L}^\infty ({\mathrm {X}})$ having a ${\mathrm {Y}}$ -orthonormal basis is automatically a free (and, in particular, projective) module and closed in $\mathrm {L}^\infty ({\mathrm {X}})$ .

The following result (see [Reference Edeko, Haase and KreidlerEHK21, Proposition 8.5 and Lemmas 8.3 and 6.8] or [Reference EllisEll87, Remark 5.16 (1)]) shows that for extensions of ergodic systems with relative discrete spectrum there exist ‘many’ invariant finitely generated submodules with an ${\mathrm {Y}}$ -orthonormal basis.

Proposition 3.8. Let $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ be an extension of ergodic measure-preserving systems. Then the following assertions are equivalent.

  1. (a) J has relative discrete spectrum.

  2. (b) The union of all finitely generated invariant $\mathrm {L}^\infty ({\mathrm {Y}})$ - submodules of $\mathrm {L}^\infty ({\mathrm {X}})$ having a ${\mathrm {Y}}$ -orthonormal basis is dense in $\mathrm {L}^1({\mathrm {X}})$ .

4 Topological models for structured extensions

Comparing Theorem 2.8 and Proposition 3.8 (combined with Remark 3.7) makes the parallelisms between structured extensions in topological dynamics and ergodic theory apparent. We now study the relation between both worlds. Recall first that, as in Example 3.5, we can always construct extensions of measure-preserving systems from extensions of topological dynamical systems by picking an invariant measure.

Definition 4.1. Let $q : (K;\varphi ) \rightarrow (L;\psi )$ be an extension of topological dynamical systems. Moreover, let $\mu \in \mathrm {P}_\varphi (K)$ be an invariant probability measure on K and $q_*\mu \in \mathrm {P}_\psi (L)$ its pushforward, that is, $q_*\mu = T_q'\mu $ . Then the extension

$$ \begin{align*} T_q : (L,q_*\mu;T_\psi) \rightarrow (K,\mu;T_\varphi), \quad f \mapsto f \circ q \end{align*} $$

is the extension of measure-preserving systems induced by $(q,\mu )$ .

With the help of Theorem 2.8 we now immediately obtain the following proposition.

Proposition 4.2. Assume that $q : (K;\varphi ) \rightarrow (L;\psi )$ is an open pseudoisometric extension with a topologically ergodic system $(L;\psi )$ . For every $\mu \in \mathrm {P}_\varphi (K)$ the induced extension $T_q : (L,q_*\mu ;T_\psi ) \rightarrow (K,\mu ;T_\varphi )$ has relative discrete spectrum.

Proof. By Theorem 2.8 the union of all closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules is dense in $\mathrm {C}(K)$ and, via the canonical map $\mathrm {C}(K) \rightarrow \mathrm {L}^1(K,\mu )$ , also dense in $\mathrm {L}^1(K,\mu )$ . However, if M is a finitely generated invariant $\mathrm {C}(L)$ submodule of $\mathrm {C}(K)$ with generators $e_1, \ldots ,e_n$ , then the $\mathrm {L}^\infty (L, q_*\mu )$ -submodule of $\mathrm {L}^\infty (K,\mu )$ generated by the canonical images of $e_1, \ldots , e_n$ in $\mathrm {L}^\infty (K,\mu )$ is also invariant. This shows the claim.

In particular, by Lemma 2.11 we can construct extensions with relative discrete spectrum from pseudoisometric extensions of minimal topological dynamical systems. In the remainder of this section we study the converse situation. Given an extension $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ of measure-preserving systems with relative discrete spectrum, can we find a pseudoisometric topological model? In order to make this question precise, we recall the following definition (cf. [Reference GlasnerGla03, §2.2] and [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 12]).

Definition 4.3. Let $J_i : ({\mathrm {Y}}_i;S_i) \rightarrow ({\mathrm {X}}_i;T_i)$ be extensions of measure-preserving systems for $i=1,2$ . An isomorphism from $J_1$ to $J_2$ is a pair $(\Psi ,\Phi )$ of an isomorphism ${\Psi : ({\mathrm {Y}}_1;S_1) \rightarrow ({\mathrm {Y}}_2;S_2)}$ and an isomorphism $\Phi : ({\mathrm {X}}_1;T_1) \rightarrow ({\mathrm {X}}_2;T_2)$ such that the diagram

commutes.

If $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ is an extension of measure-preserving systems, then a topological model for J is a pair $(q,\mu ;\Psi ,\Phi )$ such that

  • $q : (K;\varphi ) \rightarrow (L;\psi )$ is an extension of topological dynamical systems;

  • $\mu \in \mathrm {P}_\varphi (K)$ is a fully supported invariant probability measure; and

  • $(\Psi ,\Phi )$ is an isomorphism from the extension $T_q$ induced by $(q,\mu )$ to J.

Remark 4.4. We use the following observation to construct topological models. If $(q,\mu ;\Psi ,\Phi )$ is a topological model for $J: ({\mathrm {Y}}; S) \to ({\mathrm {X}}; T)$ with $q : (K;\varphi ) \rightarrow (L;\psi )$ , then

$$ \begin{align*} A_{q,\mu} := \Psi(\mathrm{C}(L)) \subseteq \mathrm{L}^\infty({\mathrm{Y}})\quad \textrm{and}\quad B_{q,\mu} := \Phi(\mathrm{C}(K)) \subseteq \mathrm{L}^\infty({\mathrm{X}}) \end{align*} $$

are invariant unital $\mathrm {C}^*$ -subalgebras of $\mathrm {L}^\infty ({\mathrm {Y}})$ and $\mathrm {L}^\infty ({\mathrm {X}})$ , respectively, being dense in the corresponding $\mathrm {L}^1$ -spaces. Moreover, $J(A) \subseteq B$ . Conversely, by Gelfand’s representation theory, for every pair $(A,B)$ of $\mathrm {L}^1$ -dense invariant unital $\mathrm {C}^*$ -subalgebras $A \subseteq \mathrm {L}^\infty ({\mathrm {Y}})$ and $B \subseteq \mathrm {L}^\infty ({\mathrm {X}})$ with $J(A) \subseteq B$ , we can construct, in a canonical way, a topological model $(q,\mu ;\Psi ,\Phi )$ for J such that $A = A_{q,\mu }$ and $B = B_{q,\mu }$ (cf. [Reference Eisner, Farkas, Haase and NagelEFHN15, Ch. 12]).

Using Theorem 2.8 and Proposition 3.8 we can always find a pseudoisometric topological model for extensions of ergodic measure-preserving systems with relative discrete spectrum.

Theorem 4.5. Let $J : (Y;S) \rightarrow (X;T)$ be an extension of ergodic measure-preserving systems with relative discrete spectrum. Then J has a topological model $(q,\mu ;\Psi ;\Phi )$ such that $q : (K;\varphi ) \rightarrow (L;\psi )$ is an open pseudoisometric extension with $(K;\varphi )$ topologically ergodic.

Proof. We define $A := \mathrm {L}^\infty ({\mathrm {Y}})$ and take B as the unital $\mathrm {C}^*$ -algebra generated by all invariant, finitely generated, projective $\mathrm {L}^\infty ({\mathrm {Y}})$ -submodules of $\mathrm {L}^\infty ({\mathrm {X}})$ which are closed in $\mathrm {L}^\infty ({\mathrm {X}})$ . Clearly, A is dense $\mathrm {L}^1({\mathrm {Y}})$ , and, in view of Remark 3.7 and Proposition 3.8, B is also dense in $\mathrm {L}^1({\mathrm {X}})$ . By Remark 4.4 we find a topological model $(q,\mu ;\Psi ,\Phi )$ for J where $q : (K;\varphi ) \rightarrow (L;\psi )$ is an extension of topological dynamical systems. We obtain that $\Phi (\mathrm {C}(L)) = A = \mathrm {L}^\infty ({\mathrm {Y}})$ . Since the system $({\mathrm {X}};T)$ is ergodic, ${\operatorname {fix}}(T_\varphi )$ is one-dimensional and therefore $(K;\varphi )$ is topologically ergodic. Also, since we have chosen A to be the whole space $\mathrm {L}^\infty ({\mathrm {Y}})$ , the induced extension q is open by [Reference EllisEll87, Corollary 1.9]. Finally, since $B = \Phi (\mathrm {C}(K))$ we obtain that $\mathrm {C}(K)$ is generated as a unital C*-algebra by all closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules. Thus, q is pseudoisometric by Theorem 2.8.

Note that the construction of the topological model in the proof of Theorem 4.5 is completely canonical. However, it is still unsatisfactory in some ways. For example, by relying on the ‘Stone model’ (that is, the topological model for the algebra $A = \mathrm {L}^\infty ({\mathrm {Y}})$ ) in the proof of Theorem 4.5, we cannot find metrizable models for extensions between separable probability spaces since $\mathrm {L}^\infty ({\mathrm {Y}})$ is only separable if it is finite-dimensional. A yet more serious problem is that, given two extensions $J_1 : (\mathrm {Z};R) \rightarrow ({\mathrm {Y}};S)$ and $J_2 : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ with relative discrete spectrum, Theorem 4.5 does not allow us to construct pseudoisometric models $q_1$ and $q_2$ which ‘fit together’ since in Theorem 4.5 the base of the constructed extension is the Stone model. This will be essential in the construction of distal models by means of successive extensions. The following result fixes these problems, at least in certain situations, by allowing us to impose that the topological model at the bottom of an extension be any specific given topological model instead of the Stone model.

Recall that a measure $\nu \in \mathrm {P}_\psi (L)$ is called ergodic if the induced measure-preserving system $(L,\nu ;T_\psi )$ is ergodic.

Theorem 4.6. Let $(L;\psi )$ be a minimal topological dynamical system, $\nu \in \mathrm {P}_\psi (L)$ a fully supported ergodic measure and $J : (L,\nu ;T_\psi ) \rightarrow ({\mathrm {X}};T)$ an extension of ergodic systems with relative discrete spectrum. Then there are

  1. (i) an open pseudoisometric extension $q : (K;\varphi ) \rightarrow (L;\psi )$ ,

  2. (ii) a fully supported ergodic measure $\mu \in \mathrm {P}_\varphi (K)$ with $q_*\mu = \nu $ , and

  3. (iii) an isomorphism $\Phi : (K,\mu ;T_\varphi ) \rightarrow ({\mathrm {X}};T)$ ,

such that $(q,\mu ;\mathrm {Id},\Phi )$ is a topological model for J. Moreover, if ${\mathrm {X}}$ is separable and L is metrizable, then K can be (non-canonically) chosen to be metrizable such that q is an isometric extension.

The challenge in proving Theorem 4.6 is, given an abundance of finitely generated invariant $\mathrm {L}^\infty (L, \nu )$ -submodules, to find an abundance of finitely generated invariant ${\mathrm {C}}(L)$ -submodules. It is non-trivial that this can be done, and it is this and only this point that forces us to restrict to ${\mathbb {Z}}$ -actions in this paper. The following lemma shows that, at least for ${\mathbb {Z}}$ -actions, finitely generated invariant $\mathrm {L}^\infty (L, \nu )$ -submodules can indeed be approximated by finitely generated invariant ${\mathrm {C}}(L)$ -submodules.

Lemma 4.7. Let $(L;\psi )$ be a topological dynamical system, $\nu \in \mathrm {P}_\psi (L)$ fully supported and ergodic, and $J : (L,\nu ;T_\psi ) \rightarrow ({\mathrm {X}};T)$ an extension. Let $M \subseteq \mathrm {L}^\infty ({\mathrm {X}})$ be an invariant $\mathrm {L}^\infty (L,\nu )$ -submodule with orthonormal basis $\{e_1, \ldots , e_n \}$ . For every $\varepsilon> 0$ there is an $(L,\nu )$ -orthonormal set $\{d_1, \ldots , d_n \} \subseteq M$ such that:

  1. (i) the $\mathrm {C}(L)$ -submodule generated by $d_1, \ldots , d_n$ is invariant (as well as closed in $\mathrm {L}^\infty ({\mathrm {X}})$ and projective); and

  2. (ii) $\lVert d_i - e_i\rVert _{\mathrm {L}^1({\mathrm {X}})} \leqslant \varepsilon $ for all $i \in \{1, \ldots ,n\}$ .

The proof rests on the following approximation result which is, in essence, due to Derrien (see [Reference DerrienDer00]). It shows that, given a measurable map with values in the compact group $\mathrm {U}(n)$ of unitary $n\times n$ matrices, one can find an arbitrarily close continuous map that is cohomologous (cf. [Reference LindenstraussLin99, Theorem 3.1]).

Lemma 4.8. Let $(L;\psi )$ be a metrizable topological dynamical system and $\mu \in \mathrm {P}_{\psi }(L)$ fully supported and ergodic. Assume that $F : L \rightarrow \mathrm {U}(n)$ is a Borel measurable map. For every $\varepsilon>0$ there are a Borel measurable map $G : L \rightarrow \mathrm {U}(n)$ and a continuous map $H : L \rightarrow \mathrm {U}(n)$ such that:

  1. (i) $\nu (\{l \in L \mid G(l) \neq \mathrm {Id}\}) \leqslant \varepsilon $ ; and

  2. (ii) $(G \circ \psi ) \cdot F \cdot G^{-1} =H$ almost everywhere.

Proof. If $ \nu $ has no atoms, then [Reference DerrienDer00, Theorem 1.1] shows the existence of a Borel measurable map $G : L \rightarrow \mathrm {U}(n)$ satisfying (ii). However, an inspection of the proof (see the remarks after [Reference DerrienDer00, Theorem 1.2]) reveals that for a given $\varepsilon>0$ one can also ensure (i).

Now assume that $\nu $ has an atom. Then there is a periodic finite orbit of measure one and therefore, since $\nu $ is fully supported, L is a discrete finite space. In particular, every (Borel measurable) map $G : L \rightarrow \mathrm {U}(n)$ is continuous and there is nothing to prove.

Proof of Lemma 4.7

As a first step, we reduce the problem to the case of a metrizable space L. So let $M \subseteq \mathrm {L}^\infty ({\mathrm {X}})$ be a finitely generated invariant $\mathrm {L}^\infty (L, \nu )$ -submodule with orthonormal basis $e_1, \ldots , e_n$ . Then

$$ \begin{align*} Te_i = \sum_{j=1}^n f_{ij} e_j \quad \textrm{for every } i \in \{1, \dots n\}, \end{align*} $$

where for $i,j \in \{1, \ldots , n\}$ (see Remark 3.7). Let $B \subseteq \mathrm {L}^\infty (L,\nu )$ be the unital invariant C*-subalgebra generated by the coefficients $f_{ij}$ for $i,j \in \{1, \ldots n\}$ . Then B is separable. Since $\mathrm {C}(L)$ is dense in $\mathrm {L}^1(L,\nu )$ , we find a separable invariant C*-subalgebra A of $\mathrm {C}(L)$ , the $\mathrm {L}^1$ -closure of which contains B. The canonical inclusion map $A \hookrightarrow \mathrm {C}(L)$ induces an extension $q : (L;\psi ) \rightarrow (M;\vartheta )$ (see Remark 2.2), that is, $T_q(\mathrm {C}(M)) = A$ . Since A is separable, the space M is metrizable (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 4.7]). We equip M with the pushforward measure $q_*\nu $ . Then $T_q$ defines an extension $T_q : ((M,q_*\nu );T_\vartheta ) \rightarrow ((L,\nu );T_\psi )$ . In particular, we obtain a new extension $JT_q : ((M,q_*\nu );T_\vartheta ) \rightarrow ({\mathrm {X}};T)$ and $\mathrm {L}^1({\mathrm {X}})$ is thus a $\mathrm {L}^\infty (M,q_*\nu )$ -module (cf. Remark 3.3). By choice of A, the $\mathrm {L}^\infty (M, q_*\nu )$ -submodule generated by $e_1, \ldots , e_n$ is still invariant. Replacing $(L;\psi )$ by $(M;\vartheta )$ and $\nu $ by $q_*\nu $ , we may therefore assume that L is metrizable.

Next, we show that we can pick representatives for the coefficients $f_{ij} \in \mathrm {L}^\infty (L, \nu )$ which define a $\mathrm {U}(n)$ -valued function. To that end, note that

Picking suitable representatives for $f_{ij} \in \mathrm {L}^\infty ({\mathrm {Y}})$ for $i,j \in \{1,\ldots ,n\}$ , which we denote by the same symbol, we therefore obtain a Borel measurable map

$$ \begin{align*} F : L \mapsto \mathrm{U}(n), \quad l \mapsto (f_{ij}(l))_{i,j} \end{align*} $$

from L to $\mathrm {U}(n)$ . For $\varepsilon> 0$ set

$$ \begin{align*} \delta := \varepsilon \cdot [2n \cdot \max \{\lVert e_i\rVert_{\mathrm{L}^\infty({\mathrm{X}})} \mid i \in \{1, \ldots,n\}\}]^{-1}. \end{align*} $$

Apply Lemma 4.8 to find a Borel measurable map

$$ \begin{align*} G : L \rightarrow \mathrm{U}(n), \quad l \mapsto (g_{ij}(l))_{i,j} \end{align*} $$

and a continuous map

$$ \begin{align*} H : L \rightarrow \mathrm{U}(n), \quad l \mapsto (h_{ij}(l))_{i,j} \end{align*} $$

such that:

  1. (i) $\nu (\{l \in L \mid G(l) \neq \mathrm {Id}\}) \leqslant \delta $ ; and

  2. (ii) $(G \circ \psi ) \cdot F =H \cdot G$ almost everywhere.

Now consider the elements $d_i := \sum _{k=1}^n g_{ik} e_k \in M\subseteq \mathrm {L}^\infty ({\mathrm {X}})$ for $i \in \{1, \ldots , n\}$ . Since

$$ \begin{align*} Td_i &= \sum_{k=1}^n (T_\psi g_{ik}) \cdot T e_k = \sum_{k=1}^n \sum_{j=1}^n (T_\psi g_{ik}) \cdot f_{kj} \cdot e_j \\ &= \sum_{j=1}^n \bigg(\sum_{k=1}^n (T_\psi g_{ik}) \cdot f_{kj}\bigg) e_j = \sum_{j=1}^n \bigg(\sum_{k=1}^n h_{ik}g_{kj}\bigg)e_j = \sum_{k=1}^n h_{ik} d_k \end{align*} $$

for every $i \in \{1, \ldots n\}$ , the $\mathrm {C}(L)$ -submodule of $\mathrm {L}^\infty ({\mathrm {X}})$ generated by $d_1, \ldots , d_n$ is invariant. Moreover, a quick computation confirms that

for $i,j \in \{1, \ldots , n\}$ , which shows that $\{d_1, \ldots , d_n\}$ is an $(L,\nu )$ -orthonormal set. In particular, the ${\mathrm {C}}(L)$ -submodule generated by $d_1, \ldots , d_n$ is free and hence closed in $\mathrm {L}^\infty ({\mathrm {X}})$ and projective. Finally, since $\nu (\{l \in L \mid G(l) \neq \mathrm {Id}\}) \leqslant \delta $ we obtain, for $i \in \{1, \ldots , n\}$ ,

$$ \begin{align*} \lVert d_i - e_i\rVert_{\mathrm{L}^1({\mathrm{X}})} &= \| \mathbb{E}_{(L, \nu)}(d_i - e_i)\|_{\mathrm{L}^1(L, \nu)} = \bigg\|\sum_{k=1}^n g_{ik} \mathbb{E}_{(L,\nu)}e_k - \mathbb{E}_{(L,\nu)}e_i\bigg\|_{\mathrm{L}^1(L,\nu)}\\ &\leqslant \delta \cdot \bigg\| \sum_{k=1}^n g_{ik} \mathbb{E}_{(L,\nu)}e_k - \mathbb{E}_{(L,\nu)}e_i\bigg\|_{\mathrm{L}^\infty(L,\nu)}\\ &\leqslant \delta \cdot \bigg\| \sum_{k=1}^n g_{ik} e_k - e_i\bigg\|_{\mathrm{L}^\infty({\mathrm{X}})} \leqslant \varepsilon. \\[-46pt] \end{align*} $$

We can now prove Theorem 4.6.

Proof of Theorem 4.6

Let B be the unital $\mathrm {C}^*$ -subalgebra generated by all closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules of $\mathrm {L}^\infty ({\mathrm {X}})$ . We show that B is dense in $\mathrm {L}^1({\mathrm {X}})$ . Since J has relative discrete spectrum, it suffices to approximate elements f contained in a finitely generated $\mathrm {L}^\infty (L, \nu )$ -submodule of $\mathrm {L}^\infty ({\mathrm {X}})$ with an orthonormal basis (see Proposition 3.8). Take an orthonormal basis $\{e_1, \ldots , e_n\}$ of such a module M. Let $f = \sum _{i=1}^n f_i e_i \in M$ for $f_1, \ldots , f_n \in \mathrm {L}^\infty (L, \nu )$ and $\varepsilon> 0$ . Set $c_1 := \sum _{i=1}^n \lVert f_i\rVert _{\mathrm {L}^\infty (L, \nu )} +1> 0$ . Using Lemma 4.7, we find an $(L,\nu )$ -orthonormal set $\{d_1, \ldots , d_n\} \subseteq M$ such that its $\mathrm {C}(L)$ -linear hull N is invariant and

$$ \begin{align*} \lVert d_i - e_i\rVert_{\mathrm{L}^1({\mathrm{X}})} \leqslant \frac{\varepsilon}{2c_1} \end{align*} $$

for all $i \in \{1, \ldots , n\}$ . Set $c_2 := \sum _{i=1}^n \lVert d_i\rVert _{\mathrm {L}^\infty ({\mathrm {X}})} +1> 0$ . Since $\mathrm {C}(L)$ is dense in $\mathrm {L}^1(L,\nu )$ , we now also find $g_1, \ldots , g_n \in {\mathrm {C}}(L)$ such that

$$ \begin{align*} \lVert f_i - g_i\rVert_{\mathrm{L}^1(L, \nu)} \leqslant \frac{\varepsilon}{2c_2}. \end{align*} $$

For $g := \sum _{i=1}^ng_i d_i \in N$ we then obtain

$$ \begin{align*} \|f - g\|_{\mathrm{L}^1({\mathrm{X}})} &\leqslant \sum_{i=1}^n \lVert f_i\rVert_{\mathrm{L}^\infty(L, \nu)} \lVert e_i - d_i\rVert_{\mathrm{L}^1({\mathrm{X}})} + \sum_{i=1}^n \lVert f_i - g_i\rVert_{\mathrm{L}^1(L, \nu)} \lVert d_i\rVert_{\mathrm{L}^\infty({\mathrm{X}})}\\ &\leqslant \varepsilon. \end{align*} $$

Since N is a closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodule of $\mathrm {L}^\infty ({\mathrm {X}})$ (use Remark 3.7), this shows that B is dense in $\mathrm {L}^1({\mathrm {X}})$ . By Gelfand theory we now find an extension $q : (K;\varphi )\rightarrow (L;\psi )$ , an ergodic measure $\mu \in \mathrm {P}_{\varphi }(K)$ with $q_*\mu = \nu $ and an isomorphism $\Phi : (K,\mu ;T_\varphi ) \rightarrow ({\mathrm {X}};T)$ with $\Phi (\mathrm {C}(L)) = B$ such that $(q,\mu ;\mathrm {Id},\Phi )$ is a topological model for J (see Remark 4.4). By definition of B and Theorem 2.8, the extension q is pseudoisometric.

Finally, assume that ${\mathrm {X}}$ is separable and L is metrizable. Then we find a sequence $(M_n)_{n \in \mathbb {N}}$ of finitely generated $\mathrm {L}^\infty (L, \nu )$ -submodules of $\mathrm {L}^\infty ({\mathrm {X}})$ with an orthonormal basis such that their union is dense in $\mathrm {L}^1({\mathrm {X}})$ . For every $n \in \mathbb {N}$ we find a sequence $(N_{n,k})_{k \in \mathbb {N}}$ of closed, invariant, finitely generated, projective $\mathrm {C}(L)$ -submodules contained in $M_n$ the union of which is dense in $M_n$ with respect to the $\mathrm {L}^1$ -norm. Let B the unital $\mathrm {C}^*$ -subalgebra of $\mathrm {L}^\infty ({\mathrm {X}})$ generated by $\{N_{n,k}\mid n,k \in \mathbb {N}\}$ . Since $\mathrm {C}(L)$ is separable (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 4.7]), $N_{n,k}$ is separable for all $n,k \in \mathbb {N}$ . Therefore B is separable. Proceeding as above yields a pseudoisometric extension $q : (K;\varphi )\rightarrow (L;\psi )$ , an ergodic measure $\mu \in \mathrm {P}_{\varphi }(K)$ with $q_*\mu = \nu $ and an isomorphism $\Phi : (K,\mu ;T_\varphi ) \rightarrow ({\mathrm {X}};T)$ with $\Phi (\mathrm {C}(L)) = B$ such that $(q,\mu ;\mathrm {Id},\Phi )$ is a topological model for J. Again using [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 4.7], we conclude that K is metrizable and therefore q is isometric (see Theorem 2.8).

5 Topological models for distal systems

With the help of Theorem 4.6, we now prove the existence of minimal distal topological models for ergodic distal measure-preserving systems. Recall that a topological dynamical system $(K;\varphi )$ is distal if the extension $q : (K;\varphi ) \rightarrow (\{\mathrm {pt}\};\mathrm {id})$ over a one-point system is distal in the sense of Definition 2.10, that is, if the following condition is satisfied: whenever $(x,y) \in K \times K$ and $(\varphi ^{n_\alpha })_{\alpha \in A}$ is a net with $\lim _\alpha \varphi ^{n_\alpha }(x) = \lim _\alpha \varphi ^{n_\alpha }(y)$ , then $x=y$ .

A typical example of a distal system is the skew-torus discussed in Example 2.5 which is given by an isometric extension of an isometric system. Put differently, it can be built from a trivial system by performing two isometric extensions. Furstenberg’s structure theorem extends this observation, stating that in fact any minimal distal system can be built up from a trivial system via successive (pseudo)isometric extensions and projective limits. We recall the latter concept (see also [Reference de VriesdV93, §E.12]).

Definition 5.1. Let I be a directed set. For every $i \in I$ let $(K_i;\varphi _i)$ be a topological dynamical system, and for $i \leqslant j$ let $q_i^j : (K_j;\varphi _j) \rightarrow (K_i;\varphi )$ be an extension. Assume that:

  1. (i) $q_i^j\circ q^k_j = q_i^k$ for all $i \leqslant j \leqslant k$ ; and

  2. (ii) $q_i^i = \mathrm {id}_{K_i}$ for every $i \in I$ .

Then the pair $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ is a projective system.

A topological dynamical system $(K;\varphi )$ , together with extensions $q_i : (K;\varphi ) \rightarrow (K_i;\varphi _i)$ for every $i \in I$ such that $q_i = q^j_i \circ q_j$ for all $i \leqslant j$ , is a projective limit of $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ if it satisfies the following universal property.

  • Whenever $(\widetilde {K};\widetilde {\varphi })$ is a topological dynamical system and $p_i : (\widetilde {K};\widetilde {\varphi }) \rightarrow (K_i;\varphi _i)$ are extensions for every $i \in I$ such that $p_i = q^j_i \circ p_j$ for all $i \leqslant j$ , then there is a unique extension $q : (\widetilde {K};\widetilde {\varphi }) \rightarrow (K;\varphi )$ such that the diagram

    commutes for every $i \in I$ .

In this case, we write

$$ \begin{align*} (K;\varphi) = \lim_{\substack{\longleftarrow\\ i}} (K_i;\varphi_i). \end{align*} $$

Remark 5.2. Every projective system $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ has a projective limit, and it is unique up to isomorphy. In fact, we obtain a concrete construction of a projective limit by considering the dynamics on the compact space

$$ \begin{align*} \bigg\{ (x_i)_{i \in I} \in \prod_{i \in I} K_i \,\bigg|\, \pi_i^j(x_j) = x_i \textrm{ for all } i \leqslant j\bigg\} \end{align*} $$

induced by the product action on $\prod _{i \in I} K_i$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Exercise 2.18]). Moreover, if $(K_i;\varphi _i)$ is minimal for every $i \in I$ , then every projective limit of $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ is also minimal (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Exercise 3.19]).

Remark 5.3. The following is an operator-theoretic view of projective limits. Suppose that $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ is a projective system and $(K;\varphi )$ , together with extensions $q_i : (K;\varphi ) \rightarrow (K_i;\varphi _i)$ for $i \in I$ , is a projective limit. Then the corresponding invariant unital $\mathrm {C}^*$ -subalgebras $A_{i} := T_{q_i}(\mathrm {C}(K_i))$ for $i \in I$ (see Remark 2.2) satisfy:

  1. (i) $A_{i} \subseteq A_{j}$ for $i \leqslant j$ ; and

  2. (ii) the union

    $$ \begin{align*} \bigcup_{i \in I} A_i \end{align*} $$
    is dense in $\mathrm {C}(K)$

(see [Reference Eisner, Farkas, Haase and NagelEFHN15, Exercise 4.16]). Conversely, assume that $(A_i)_{i \in I}$ is a net of invariant unital $\mathrm {C}^*$ -subalgebras $A_{i} \subseteq \mathrm {C}(K)$ for $i \in I$ satisfying (i) and (ii). For every $i \in I$ we then find an extension $q_i : (K;\varphi ) \rightarrow (K_i;\varphi _i)$ such that $A_{i} = T_{q_i}(\mathrm {C}(K_i))$ (see Remark 2.2) and the canonical inclusion maps $A_{i} \hookrightarrow A_{j}$ for $i \leqslant j$ induce extensions $q_{i}^j : (K_j;\varphi _j) \rightarrow (K_i;\varphi _i)$ between the associated systems. A moment’s thought reveals that $(K;\varphi )$ is a projective limit of the projective system $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ .

The observations discussed in Remark 5.3 are helpful for showing that a system is a projective limit of certain factors with specific properties. We demonstrate this by proving the following lemma which will soon be important.

Lemma 5.4. Let $(K;\varphi )$ be a topological dynamical system. Then there are

  1. (i) an inductive system $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ of metrizable systems, and

  2. (ii) extensions $q_i : (K;\varphi ) \rightarrow (K_i;\varphi _i)$ for every $i \in I$ ,

such that $(K;\varphi )$ together with the extensions $q_i$ for $i \in I$ is a projective limit of $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ .

Proof. Let I be the family of finite subsets of $\mathrm {C}(K)$ ordered by set inclusion. For every $i \in I$ let $A_i$ be the invariant unital $\mathrm {C}^*$ -subalgebra generated by i. Then $A_i$ is separable for every $i \in I$ and the net $(A_i)_{i \in I}$ satisfies properties (i) and (ii) of Remark 5.3. By Remark 5.3 we therefore find a projective system $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ and extensions $q_i : (K;\varphi ) \rightarrow (K_i;\varphi _i)$ for $i \in I$ such that $(K;\varphi )$ is a projective limit of $(((K_i;\varphi _i))_{i \in I}, (q_i^j)_{i \leqslant j})$ and $T_{q_i}(\mathrm {C}(K_i)) = A_i$ for every $i \in I$ . Since $A_i$ is separable, $K_i$ is metrizable for every $i \in I$ (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 4.7]), which proves the claim.

Let us now recall the famous Furstenberg structure theorem for minimal distal systems (see [Reference AuslanderAus88, Ch. 7] and [Reference de VriesdV93, §V.3]).

Theorem 5.5. For a minimal system $(K;\varphi )$ the following assertions are equivalent.

  1. (a) The system $(K;\varphi )$ is distal.

  2. (b) There are an ordinal $\eta _0$ and a projective system $(((K_\eta ;\varphi _\eta ))_{\eta \leqslant \eta _0}, (q_\eta ^\sigma )_{\eta \leqslant \sigma })$ such that:

    1. (i) $(K_1;\varphi _1)$ is a trivial system $(\{\mathrm {pt}\};\mathrm {id})$ ;

    2. (ii) $q_{\eta }^{\eta +1}$ is pseudoisometric for every $\eta < \eta _0$ ;

    3. (iii) $(K_\eta ;\varphi _\eta ) = \lim _{\gamma < \eta } (K_\gamma ;\varphi _\gamma )$ for every limit ordinal $\eta \leqslant \eta _0$ .

One can take part (b) of Theorem 5.5 as an inspiration for the concept of measurably distal systems. To formulate this concept, we briefly recall the notion of inductive limits for measure-preserving systems (see [Reference Eisner, Farkas, Haase and NagelEFHN15, §13.5]).

Definition 5.6. Let I be a directed set. For every $i \in I$ , let $({\mathrm {X}}_i;T_i)$ be a measure-preserving system, and for $i \leqslant j$ let $J_i^j : ({\mathrm {X}}_i;T_i) \rightarrow ({\mathrm {X}}_j;T_j)$ be an extension. Suppose that:

  1. (i) $J_j^k J_i^j = J_i^k$ for $i \leqslant j \leqslant k$ ; and

  2. (ii) $J_i^i = \mathrm {Id}$ for every $i \in I$ .

Then the pair $((({\mathrm {X}}_i;T_i))_{i \in I}, (J_i^j)_{i \leqslant j})$ is an inductive system.

A measure-preserving system $({\mathrm {X}};T)$ , together with extensions $J_i : ({\mathrm {X}}_i;T_i) \to ({\mathrm {X}};T)$ such that $J_i = J_j J_i^j$ for $i \leqslant j$ , is an inductive limit of $((({\mathrm {X}}_i;T_i))_{i \in I}, (J_i^j)_{i \leqslant j})$ if it satisfies the following universal property.

  • Whenever $({\mathrm {Y}};S)$ is a measure-preserving system and $I_i : ({\mathrm {X}}_i;T_i) \to ({\mathrm {Y}};S)$ are extensions with $I_i = I_j J_i^j$ for $i \leqslant j$ , then there is a unique extension $J : ({\mathrm {X}};T) \to ({\mathrm {Y}};S)$ such that the diagram

    commutes for every i.

We then write

$$ \begin{align*} ({\mathrm{X}};T) = \lim_{\substack{\longrightarrow\\ i}} ({\mathrm{X}}_i;T_i). \end{align*} $$

Every inductive system has an inductive limit (see [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 13.38]) and it is unique up to isomorphy. We now recall the definition of distal systems used by Furstenberg [Reference FurstenbergFur77, Definition 8.3].

Definition 5.7. A measure-preserving system $({\mathrm {X}};T)$ is distal if there are an ordinal $\eta _0$ and an inductive system $(((X_\eta ;T_\eta ))_{\eta \leqslant \eta _0}, (J_\eta ^\sigma )_{\eta \leqslant \sigma })$ such that:

  1. (i) $({\mathrm {X}}_1;T_1)$ is a trivial system $(\{\mathrm {pt}\};\mathrm {Id})$ ;

  2. (ii) $J_\eta ^{\eta +1}$ has relatively discrete spectrum for every $\eta < \eta _0$ ;

  3. (iii) $(X_\eta ;T_\eta ) = \lim _{\mu < \eta } (X_\mu ;T_\mu )$ for every limit ordinal $\mu \leqslant \eta _0$ .

Remark 5.8. If ${\mathrm {X}}$ is a standard probability space, then there is an equivalent definition in terms of so-called separating sieves (see [Reference Parry, Auslander and GottschalkPar68] and [Reference ZimmerZim76, Theorem 8.7]).

The measure-preserving system given by the skew-torus (see Example 3.5) is a standard example for a distal measure-preserving system. By definition, it is obtained by equipping a topologically distal system with an invariant probability measure. Our main result, generalizing [Reference LindenstraussLin99, Theorem 4.4], shows that, up to an isomorphism, every ergodic distal system can be obtained in this way. Moreover, the proof reveals a canonical choice for such a minimal distal model of a given distal ergodic measure-preserving system.

Theorem 5.9. Let $({\mathrm {X}};T)$ be an ergodic distal measure-preserving system. Then there are a minimal distal topological dynamical system $(K;\varphi )$ and a fully supported ergodic measure $\mu \in \mathrm {P}_{\varphi }(K)$ such that $({\mathrm {X}};T)$ is isomorphic to $(K,\mu ;T_\varphi )$ . If ${\mathrm {X}}$ is separable, then K can be (non-canonically) chosen to be metrizable.

The following lemma (cf. the proof of [Reference LindenstraussLin99, Theorem 4.4]) is the last missing ingredient for the proof of Theorem 5.9.

Lemma 5.10. If $(K;\varphi )$ is a distal topological dynamical system and there is a fully supported ergodic measure $\mu \in \mathrm {P}_\varphi (K)$ , then $(K;\varphi )$ is minimal.

Proof. Assume first that K is metrizable. Then the existence of a fully supported ergodic measure guarantees the existence of a point $x \in K$ with dense orbit $\{\varphi ^n(x)\mid n \in {\mathbb {Z}}\}$ , use Poincaré recurrence or Birkhoff’s ergodic theorem (see [Reference Katok and HasselblattKH95, Proposition 4.1.13]). But then $(K;\varphi )$ is already minimal since a distal system decomposes into a disjoint union of minimal systems (see [Reference AuslanderAus88, Corollary 7]).

If K is not metrizable, we use Lemma 5.4 to write $(K;\varphi )$ as a projective limit of metrizable factors $(K_i;\varphi _i)$ for $i \in I$ . Since $(K_i;\varphi _i)$ is distal and admits a fully supported ergodic measure (recall that the pushforward of an ergodic measure is again ergodic), we obtain that $(K_i;\varphi )$ is minimal for every $i \in I$ . Using that a projective limit of minimal systems is minimal (see Remark 5.2), we obtain that $(K;\varphi )$ is itself minimal.

Proof of Theorem 5.9

For an ergodic distal measure-preserving system $({\mathrm {X}}; T)$ take an ordinal $\eta _0$ and an inductive system

$$ \begin{align*} (((X_\eta;T_\eta))_{\eta \leqslant \eta_0}, (J_\eta^\sigma)_{\eta \leqslant \sigma}) \end{align*} $$

as in Definition 5.7. Moreover, we write $J_\eta : ({\mathrm {X}}_\eta ;T_\eta ) \rightarrow ({\mathrm {X}};T)$ for the corresponding extensions for every $\eta \leqslant \eta _0$ . We now recursively construct

  • a projective system $(((K_\eta ;\varphi _\eta ))_{\eta \leqslant \eta _0}, (q_\eta ^\sigma )_{\eta \leqslant \sigma })$ ,

  • ergodic measures $\mu _{\eta } \in \mathrm {P}_{\varphi _\eta }(K_\eta )$ for every $\eta \leqslant \eta _0$ , and

  • isomorphisms $\Phi _\eta : (K_\eta ,\mu _\eta ;T_{\varphi _\eta }) \rightarrow ({\mathrm {X}}_\eta ;T_\eta )$ for every $\eta \leqslant \eta _0$ ,

such that $(q_\eta ^\sigma ,\mu _\sigma ;\Phi _\eta ,\Phi _\sigma )$ is a topological model for $J_\eta ^\sigma $ for all $\eta \leqslant \sigma \leqslant \eta _0$ and such that $(((K_\eta ;\varphi _\eta ))_{\eta \leqslant \eta _0}, (q_\eta ^\sigma )_{\eta \leqslant \sigma })$ is a projective system of minimal distal systems satisfying all the properties of Theorem 5.5(b). From this the claim follows.

Let $(K_1;\varphi _1)$ be a trivial system $(\{\mathrm {pt}\};\mathrm {id})$ , $\mu _1$ the unique probability measure on $K_1$ and $\Phi _1 : (K_1,\mu _1;T_{\varphi _1}) \rightarrow ({\mathrm {X}}_1;T_1)$ the identity operator. Now assume that $\eta \leqslant \eta _0$ is an ordinal and suppose we have already constructed $(K_\gamma ;\varphi _\gamma )$ for every $\gamma < \eta $ ; $q_\gamma ^\sigma $ for $\gamma \leqslant \sigma < \eta $ ; $\mu _{\gamma }$ for $\gamma < \eta $ ; and $\Phi _\gamma $ for $\gamma < \eta $ . We have to consider two cases.

  1. (i) Assume that $\eta $ is a successor ordinal, that is, $\eta = \gamma +1$ for an ordinal $\gamma $ . Since $(K_\gamma ,\mu _{\gamma };T_{\varphi _{\gamma }})$ is isomorphic to $(X_\gamma ;T_{\gamma })$ via $\Phi _\gamma $ , we can apply Theorem 4.6 to find

    • a pseudoisometric extension $q_{\gamma }^{\eta } : (K_{\eta };\varphi _{\gamma }) \rightarrow (K_\gamma ;\varphi _{\gamma })$ ,

    • a fully supported ergodic measure $\mu _{\eta } \in \mathrm {P}_{\varphi _{\eta }}(K_{\eta })$ with $(q_{\gamma }^{\eta })_*\mu _{\eta } = \mu _{\gamma }$ , and

    • an isomorphism $\Phi _{\eta } : (K_{\eta },\mu _{\eta };T_{\varphi _{\eta }}) \rightarrow (X_{\eta };T_{\eta })$ ,

    such that $(q_{\gamma }^{\eta },\mu _{\eta };\Phi _{\gamma },\Phi _{\eta })$ is a topological model for $J_{\gamma }^\eta $ . Since $(K_\gamma ;\varphi _{\gamma })$ is distal and $q_{\gamma }^{\eta }$ is pseudoisometric, the system $(K_{\eta };\varphi _{\eta })$ is also distal. Moreover, $(K_{\eta };\varphi _{\eta })$ is minimal by Lemma 5.10. We set $q_\sigma ^{\eta } := q_\sigma ^\gamma \circ q_{\gamma }^{\eta } $ for every $\sigma < \gamma $ .

  2. (ii) If $\eta \leqslant \eta _0$ is a limit ordinal, we let $(K_{\eta };\varphi _{\eta })$ , together with maps $q_\gamma ^\eta : (K_\eta ;\varphi _\eta ) \rightarrow (K_\gamma ;\varphi _\gamma )$ for $\gamma < \eta $ , be a projective limit of the projective system $(((K_\gamma ;\varphi _\gamma ))_{\gamma < \eta }, (q_\gamma ^\sigma )_{\gamma \leqslant \sigma })$ . Moreover, let $\mu _{\eta }$ be the ergodic measure on $(K_{\eta };\varphi _{\eta })$ induced by the net $(\mu _\gamma )_{\gamma < \eta }$ (cf. [Reference Eisner, Farkas, Haase and NagelEFHN15, Exercise 10.13]), that is, $\mu _{\eta } \in \mathrm {C}(K_\eta )'$ is uniquely determined by the identity $(q_\gamma ^\eta )_{*}\mu _\eta = \mu _{\gamma }$ for every $\gamma < \eta $ . By setting

    $$ \begin{align*} \Phi_{\eta}(T_{q_\gamma^\eta}f) := J_\gamma^\eta \Phi_\gamma f \end{align*} $$
    for every $f \in \mathrm {C}(K_{\gamma })$ and $\gamma < \eta $ we obtain a (well-defined) map
    $$ \begin{align*} \Phi_{\eta} : \bigcup_{\gamma < \eta} T_{q_\gamma^\eta}(\mathrm{C}(K_{\gamma})) \subseteq \mathrm{C}(K_\eta) \rightarrow \mathrm{L}^1({\mathrm{X}}_\eta) \end{align*} $$
    which extends to an isometric isomorphism $\Phi _{\eta } : \mathrm {L}^1(K_\eta ,\mu _\eta ) \rightarrow \mathrm {L}^1({\mathrm {X}}_\eta )$ intertwining the dynamics.

It is clear from the construction that $(q_\eta ^\sigma ,\mu _\sigma ;\Phi _\eta ,\Phi _\sigma )$ is a topological model for $J_\eta ^\sigma $ for all $\eta \leqslant \sigma \leqslant \eta _0$ .

Finally, if ${\mathrm {X}}$ is separable, then we can choose metric models in (i) (see Theorem 4.6). Moreover, in (ii) we can find a subsequence $(((X_{\gamma _n};T_{\gamma _n}))_{n \in \mathbb {N}}, (J_{\gamma _{n}}^{\gamma _k})_{n \leqslant k})$ of the projective system $(((X_\gamma ;T_\gamma ))_{\gamma \leqslant \eta }, (J_\gamma ^\sigma )_{\gamma \leqslant \sigma })$ such that $({\mathrm {X}}_\eta ;T_\eta )$ is still the inductive limit of that subsequence (this is an easy consequence of the characterization (iii) of inductive limits in [Reference Eisner, Farkas, Haase and NagelEFHN15, Theorem 13.35]). By considering the now metrizable projective limit of $(((K_{\gamma _n};\varphi _{\gamma _n}))_{n}, (q_{\gamma _n}^{\gamma _k})_{n \leqslant k})$ in (ii) and then proceeding as before, we also obtain metrizable models in (ii).

Remark 5.11. Our approach to the theorem of Lindenstrauss unveils a connection between topological and measure-preserving distal systems at a categorical level. Inspecting the definition of the canonical minimal distal model $\mathrm {Mod}({\mathrm {X}};T) := (K;\varphi )$ of an ergodic distal measure-preserving system $({\mathrm {X}};T)$ in the proof of Theorem 5.9 shows that the assignment $({\mathrm {X}};T) \mapsto \mathrm {Mod}({\mathrm {X}};T)$ is actually functorial: every extension $J : ({\mathrm {Y}};S) \rightarrow ({\mathrm {X}};T)$ of ergodic distal measure-preserving systems induces an extension $\mathrm {Mod}(J) : \mathrm {Mod}({\mathrm {X}};T) \rightarrow \mathrm {Mod}({\mathrm {Y}};S)$ between the corresponding canonical topological models. In this way, we obtain a (contravariant) functor $\mathrm {Mod}$ from the category of ergodic distal measure-preserving systems to the category of minimal distal topological dynamical systems. It is noteworthy, however, that, even though we can also construct distal ergodic measure-preserving systems from distal minimal systems (by simply choosing an ergodic invariant probability measure), the functor $\mathrm {Mod}$ does not define an equivalence between the two categories. In fact, if $({\mathrm {X}};T)$ is an ergodic distal measure-preserving system and $(K;\varphi )$ its canonical model, then every eigenfunction of T corresponds to a continuous eigenfunction of $T_\varphi $ . With this observation one can readily show that a minimal distal system $(K;\varphi )$ possessing

  1. (i) a unique invariant Borel probability measure $\mu $ , and

  2. (ii) an eigenfunction $f \in \mathrm {L}^\infty (K,\mu )\setminus \mathrm {C}(K)$ with respect to $T_\varphi $

cannot be isomorphic to any canonical model $\mathrm {Mod}({\mathrm {X}};T)$ of an ergodic distal measure-preserving system $({\mathrm {X}};T)$ . An example due to Parry (see [Reference ParryPar74, §3]) demonstrates that such systems indeed exist and hence $\mathrm {Mod}$ does not define a categorical equivalence.

Remark 5.12. In his paper [Reference LindenstraussLin99], Lindenstrauss also discusses under what conditions an ergodic distal measure-preserving system has a distal model which is strictly ergodic (that is, minimal with a unique invariant Borel probability measure; see also [Reference Gutman and LianGL19]). It is therefore an interesting problem to determine the cases in which the canonical model constructed in this paper is strictly ergodic.

Acknowledgements

The authors thank Rainer Nagel for helpful comments, and the MFO for providing a fruitful atmosphere for working on this project. They are also grateful to the referee for their valuable suggestions. Henrik Kreidler also acknowledges the financial support from the DFG (project number 451698284).

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