1. Introduction
Silting-discreteness is a finiteness condition on a triangulated category, namely, a silting-discrete triangulated category admits only finitely many silting objects in any interval of silting objects [Reference Aihara5]; actually, the set of silting objects has a poset structure [Reference Aihara and Iyama9]. In the case, we can fully grasp the whole picture of silting objects, and such a triangulated category has so nice structure. For example, a silting-discrete triangulated category satisfies a Bongartz-type condition; that is, any presilting object is partial silting [Reference Aihara and Mizuno10]. For an ST-pair $(\mathcal {C}, \mathcal {D})$ , $\mathcal {C}$ is silting-discrete if and only if $\mathcal {D}$ is t-discrete if and only if every bounded t-structure in $\mathcal {D}$ is algebraic; moreover, in the case, the stability space of $\mathcal {D}$ is contractible [Reference Adachi, Mizuno and Yang4] (see also [Reference Pauksztello, Saorin and Zvonareva47]).
In general, it is very hard to check if a given triangulated category is silting-discrete. Thus, an extremely powerful tool was introduced [Reference Adachi, Aihara and Chan1], [Reference Aihara5], [Reference Aihara and Mizuno10], and it is applied to the perfect derived category of a finite-dimensional algebra over an algebraically closed field; we know several algebras with silting-discrete perfect derived categories, say silting-discrete algebras [Reference Adachi, Aihara and Chan1], [Reference Adachi and Kase3], [Reference Aihara5], [Reference Aihara, Honma, Miyamoto and Wang8]–[Reference Aihara and Mizuno10], [Reference August16], [Reference August and Dugas17], [Reference Broomhead, Pauksztello and Ploog21], [Reference Eisele, Janssens and Raedschelders27]. Typical examples of silting-discrete algebras are local algebras, piecewise hereditary algebras of Dynkin type, and representation-finite symmetric algebras. It was also shown by [Reference Yao and Yang56] that for an ST-triple $(\mathcal {C}, \mathcal {D}, T)$ if $\mathcal {C}$ is T-discrete, then it is silting-discrete, which implies that any derived-discrete algebra is silting-discrete; we will also observe the result in Appendix A. We obtain from [Reference Adachi, Mizuno and Yang4] that if $(\mathcal {C}, \mathcal {D})$ is a $(d+1)$ -Calabi–Yau pair for $d=1,2$ , then $\mathcal {C}$ is silting-discrete if and only if the endomorphism algebra of a silting object is $\tau $ -tilting finite, which leads to the fact that for the derived preprojective algebra $\Gamma :=\Gamma _{d+1}(Q)$ of a finite quiver Q with $H^0(\Gamma )$ finite-dimensional (note that it is a nonpositive dg algebra), the perfect derived category of $\Gamma $ is silting-discrete if and only if Q is Dynkin.
The aim of this paper is to investigate when the silting-discreteness is inherited. For example, derived equivalences certainly transmit the silting-discreteness. Tensoring a local algebra also conveys the property [Reference Aihara and Honma7]. One of the main theorems of this paper (Theorem 2.10) states that a full triangulated subcategory of a silting-discrete triangulated category is also silting-discrete. Moreover, we show that a homological epimorphism of (nonpositive) dg algebras induces the silting-discreteness (Theorem 2.15). These lead us to the following results.
Theorem 1 (Corollaries 2.11 and 2.22).
Let $\Lambda $ be a finite-dimensional algebra over an algebraically closed field. Assume that $\Lambda $ is silting-discrete. Then we have the following.
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(1) For an idempotent e of $\Lambda $ , the truncation $e\Lambda e$ is silting-discrete.
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(2) If e is a stratifying idempotent of $\Lambda $ , then $\Lambda /\Lambda e\Lambda $ is silting-discrete.
We remark that quotients of algebras always inherit the $\tau $ -tilting finiteness [Reference Demonet, Iyama, Reading, Reiten and Thomas26], but not necessarily the silting-discreteness (§2.5).
The Bongartz-type condition is also one of the most important subjects in silting theory. We naturally ask whether or not the Bongartz-type condition always holds.Footnote 1 For example, silting-discrete triangulated categories satisfy the Bongartz-type condition and every 2-term presilting object can be completed to a silting object [Reference Aihara5], [Reference Aihara and Mizuno10]. Note that the tilting version (i.e., is a pretilting object partial tilting?) often fails [Reference Liu, Vitoria and Yang40], [Reference Rickard48] (see Example B.8). Theorem 1 and its proof provide a new Bongartz-type lemma under a certain condition (see Corollary 2.17 for a general setting, which recovers the 2-term version).
Theorem 2 (Corollary 2.18(2)).
Let e be an idempotent of $\Lambda $ . Then a presilting object of the perfect derived category of $\Lambda $ generating the thick closure of $e\Lambda $ is partial silting.
As a corollary of Theorem 1, we classify silting-discrete simply connected tensor algebras; note that the tensor algebra of three nonlocal algebras is never silting-discrete [Reference Aihara and Honma7]. Also, we obtain a surprising result, which says that a representation-finite self-injective algebra is not necessarily silting-discrete.
Theorem 3 (Proposition 3.1, Theorems 3.4 and 3.6).
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(1) A simply connected algebra is silting-discrete if and only if it is piecewise hereditary of Dynkin type.
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(2) Let A and B be finite-dimensional nonlocal simply connected algebras over an algebraically closed field K. Then the following are equivalent:
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(i) $A\otimes _KB$ is silting-discrete;
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(ii) it is piecewise hereditary of type $D_4, E_6$ , or $E_8$ ;
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(iii) it is derived equivalent to a commutative ladder of degree $\leq 4$ .
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(3) The self-injective Nakayama algebra with n simple modules of length r is not silting-discrete if (i) $r=3, 4$ and $n\geq 11$ ; (ii) $r=5,6$ and $n\geq r+8$ ; or (iii) $r\geq 7$ and $n\geq 2r+1$ .
2. Main results
Throughout this paper, let $\mathcal {T}$ be a triangulated category which is Krull–Schmidt, K-linear for an algebraically closed field K, and Hom-finite. For an object T of $\mathcal {T}$ , its thick closure is denoted by $\operatorname {\mathsf {thick}} T$ ; that is, it is the smallest thick subcategory of $\mathcal {T}$ containing T.
Silting objects play a central role in this paper.
Definition 2.1. Let T be an object of $\mathcal {T}$ .
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(1) We say that T is presilting (pretilting) if it satisfies $\operatorname {Hom}_{\mathcal {T}}(T, T[i])=0$ for any $i>0\ (i\neq 0)$ .
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(2) A presilting (pretilting) object T is said to be silting (tilting) provided $\mathcal {T}=\operatorname {\mathsf {thick}}\ T$ .
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(3) A partial silting (partial tilting) object is defined to be a direct summand of some silting (tilting) object.
Notation 2.2. We use the following notations.
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• Denote by $\operatorname {\mathsf {silt}}\mathcal {T}$ the set of isomorphism classes of basic silting objects of $\mathcal {T}$ .
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• We always suppose that $\operatorname {\mathsf {silt}}\mathcal {T}$ is nonempty.
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• For a silting object A of $\mathcal {T}$ and $d>0$ , $\mathsf {d}_{A}\operatorname{-silt}\mathcal {T}:=\{T\in \operatorname {\mathsf {silt}}\mathcal {T}\ |\ A\geq T\geq A[d-1] \}$ .
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• Let S be a presilting object of $\mathcal {T}$ . The subset $\operatorname {\mathsf {silt}}_S\mathcal {T}$ of $\operatorname {\mathsf {silt}}\mathcal {T}$ consists of all silting objects having S as a direct summand.
As terminology, for presilting objects T and U of $\mathcal {T}$ , we use $T\geq U$ if $\operatorname {Hom}_{\mathcal {T}}(T, U[i])=0$ for every $i>0$ . This actually gives a partial order on $\operatorname {\mathsf {silt}}\mathcal {T}$ [Reference Aihara and Iyama9, Th. 2.11].
We define the silting-discreteness of $\mathcal {T}$ , which is the main theme of this paper.
Definition 2.3.
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(1) We say that $\mathcal {T}$ is silting-discrete if it has a silting object A such that for any $d>0$ , the set $\mathsf{d}_{A}\operatorname{-silt}\mathcal {T}$ is finite (see [Reference Aihara5, Prop. 3.8] for equivalent conditions of silting-discreteness). (As a convention, a triangulated category without silting object is also called silting-discrete.)
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(2) For a silting object A of $\mathcal {T}$ , we call $\mathcal {T}$ $2_A$ -silting finite if $ \mathsf{2}_{A}\operatorname{-silt}\mathcal {T}$ is a finite set.
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(3) A 2-silting finite triangulated category is defined to be $2_A$ -silting finite for every silting object A of $\mathcal {T}$ .
Remark 2.4.
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(1) The notion of $2_A$ -silting finiteness is nothing but that of $\tau $ -tilting finiteness for $\operatorname {End}_{\mathcal {T}}(A)$ [Reference Demonet, Iyama and Jasso25, Cor. 2.8]. For $\tau $ -tilting theory, we refer to [Reference Adachi, Iyama and Reiten2].
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(2) The silting-discreteness is preserved under triangle equivalences, but the $2_A$ -silting finiteness is not always so; it depends on the choice of silting objects A.
Let us recall several results in [Reference Aihara5], [Reference Aihara and Mizuno10].
Proposition 2.5. Let A be a silting object, and let T be a presilting object of $\mathcal {T}$ .
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(1) [Reference Aihara5, Prop. 2.16] If $A\geq T\geq A[1]$ , then T is a direct summand of a silting object lying in the interval between A and $A[1]$ .
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(2) [Reference Aihara and Mizuno10, Prop. 2.14] Assume that $\mathcal {T}$ is $2_A$ -silting finite. If $A\geq T\geq A[2]$ , then there exists a silting object B of $\mathcal {T}$ satisfying $A\geq B\geq T\geq B[1]\geq A[2]$ .
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(3) [Reference Aihara and Mizuno10, Prop. 2.14] Assume that $\mathcal {T}$ is silting-discrete. Then there is a silting object P of $\mathcal {T}$ with $P\geq T\geq P[1]$ .
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(4) [Reference Aihara and Mizuno10, Th. 2.4] $\mathcal {T}$ is silting-discrete if and only if it is 2-silting finite.
In the following, we investigate the silting-discreteness of triangulated categories:
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• Full triangulated subcategories inherit the silting-discreteness (2.1);
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• Recollements make an influence on silting-discreteness (2.2).
Moreover, we will also consider silting-discrete algebras as these corollaries.
Let $\Lambda $ be a finite-dimensional K-algebra which is basic and ring-indecomposable, and modules are always finite-dimensional and right unless otherwise noted. The perfect derived category of $\Lambda $ is denoted by $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ .
We say that $\Lambda $ is silting-discrete if so is $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . Here is an example of silting-discrete algebras which we should first observe; one frequently uses it in the rest of this paper.
Example 2.6. A piecewise hereditary algebra of type $\mathcal {H}$ , that is, the algebra is derived equivalent to a hereditary abelian category $\mathcal {H}$ with a tilting object, is silting-discrete if and only if $\mathcal {H}$ is of Dynkin type.
Let Q be a (finite) quiver. For an arrow $\alpha : i\to j$ of Q, we consider the formal inverse $\alpha ^{-1}:j\to i$ and define the virtual degree by $\deg (\alpha ^\pm )=\pm 1$ (double-sign corresponds). The virtual degree of a walk (a sequence of successive arrows and formal inverses) is defined by $\log $ -rule: $\deg (\alpha \beta )=\deg (\alpha )+\deg (\beta )$ . We say that Q is gradable if any closed walk has virtual degree 0. Here, a closed walk is a walk whose start and goal coincide. For instance, every tree quiver (i.e., the underlying graph is tree) is gradable. Note that a gradable quiver admits no oriented cycle; but the converse does not necessarily hold.
We observe silting-discrete algebras with radical square zero.
Proposition 2.7. Let $\Lambda $ be the radical-square-zero algebra given by a gradable quiver Q. Then $\Lambda $ is silting-discrete if and only if Q is Dynkin.
Proof. It follows from [Reference Yang55, Th. 4.4] that $\Lambda $ is derived equivalent to $KQ$ .
Note that there is a silting-discrete radical-square-zero algebra presented by an ungradable non-Dynkin acyclic quiver (Example 2.19).
We say that $\Lambda $ is gentle if it is presented by a quiver Q with ideal I such that:
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(1) for any vertex of Q, there exist at most two incoming and at most two outgoing arrows;
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(2) for each arrow $x: i\to j$ of Q, the number of arrows y stopping at i (starting from j) with $yx\not \in I$ ( $xy\not \in I$ ) is at most 1;
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(3) for each arrow $x: i\to j$ of Q, the number of arrows y stopping at i (starting from j) with $yx\in I$ ( $xy\in I$ ) is at most 1;
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(4) all relations in I are paths of length 2.
A quiver Q is called one-cycle provided its underlying graph contains exactly one cycle. A gentle one-cycle algebra is defined to be a gentle algebra given by a one-cycle quiver. We say that a gentle one-cycle algebra satisfies the clock condition if the numbers of clockwise- and counterclockwise-oriented relations on the cycle coincide.
The following proposition is also useful.
Proposition 2.8. A gentle one-cycle algebra $\Lambda $ is silting-discrete if and only if it does not satisfy the clock condition.
Proof. Assume that $\Lambda $ satisfies the clock condition. By [Reference Assem and Skowronski15, Th. (A)], we see that $\Lambda $ is a piecewise hereditary algebra of type $\widetilde {A}$ , which is not silting-discrete.
Assume that $\Lambda $ does not satisfy the clock condition. It follows from [Reference Vossieck53, Theorem] that $\Lambda $ is derived-discrete, and so it is silting-discrete by [Reference Yao and Yang56, Exam. 3.9 and Cor. 4.2].
Let us observe the silting-discreteness of type $\widetilde {A}$ with commutative relation.
Proposition 2.9. Let $\Lambda $ be the algebra given by the quiver of type $\widetilde {A_{p,q}}$ with commutative relation; suppose that $1<p\leq q$ . Then $\Lambda $ is silting-discrete if and only if $p=2$ and any q or $p=3$ and $q=3, 4, 5$ .
Proof. Let Q be the quiver . Since $\Lambda $ is the one-point extension of the path algebra $KQ$ by the indecomposable injective module corresponding to the vertex $\bigstar $ , we see that it is derived equivalent to the one-point extension of $KQ$ by the indecomposable projective module corresponding to the vertex $\bigstar $ [Reference Barot and Lenzing18, Th. 1], which is the path algebra of the quiver $\widetilde {Q}$
Hence, it turns out that $\Lambda $ is silting-discrete if and only if so is $K\widetilde {Q}$ if and only if one of the desired conditions holds.
2.1. Full triangulated subcategories
The following is the first main theorem.
Theorem 2.10. Let $\mathcal {U}$ be a full triangulated subcategory of $\mathcal {T}$ . If $\mathcal {T}$ is silting-discrete, then so is $\mathcal {U}$ .
Proof. We show that $\mathcal {U}$ is 2-silting finite; hence, it is silting-discrete by Proposition 2.5(4). Let T be a silting object in $\mathcal {U}$ . As T is presilting in $\mathcal {T}$ , we obtain a silting object A satisfying $A\geq T\geq A[1]$ by Proposition 2.5(3). Let U be a silting object of $\mathcal {U}$ with $T\geq U\geq T[1]$ . Since there is a triangle $T_1\to T_0\to U\to T_1[1]$ with $T_0, T_1\in \operatorname {\mathsf {add}} T$ in $\mathcal {U}$ [Reference Aihara and Iyama9, Prop. 2.24], we have inequalities $A\geq U\geq A[2]$ . Proposition 2.5(1) and (2) lead to the fact that U is a direct summand of a silting object lying in the interval between A and $A[2]$ . As the interval in $\operatorname {\mathsf {silt}}\mathcal {T}$ is a finite set, we deduce that $\{U\in \operatorname {\mathsf {silt}}\mathcal {U}\ |\ T\geq U\geq T[1] \}$ is also finite.
A typical example of fully faithful functors is the triangle functor $-\otimes _{e\Lambda e}e\Lambda :\mathsf {K^b}(\operatorname {\mathsf {proj}} e\Lambda e)\to \mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ for an idempotent e of $\Lambda $ . This yields a corollary of Theorem 2.10, which says that taking idempotent truncations brings the silting-discreteness from the original.
Corollary 2.11. Let e be an idempotent of $\Lambda $ . If $\Lambda $ is silting-discrete, then so is $e\Lambda e$ .
2.2. Recollements
In this subsection, we investigate an impact of recollements on silting-discreteness.
Let us begin with the study of silting reductions [Reference Iyama and Yang31], which enable us to realize the Verdier quotient of $\mathcal {T}$ by the thick closure of a presilting object as a certain subfactor category of $\mathcal {T}$ and which make isomorphisms of silting posets.
Let S be a presilting object of $\mathcal {T}$ and put $\mathcal {S}:=\operatorname {\mathsf {thick}} S$ . The Verdier quotient of $\mathcal {T}$ by $\mathcal {S}$ is denoted by $\mathcal {T}/\mathcal {S}$ . Take a full subcategory $\mathcal {Z}$ of $\mathcal {T}$ as follows:
We denote by $\frac {\mathcal {Z}}{[S]}$ the additive quotient of $\mathcal {Z}$ modulo the ideal $[S]$ , which admits a triangle structure [Reference Iyama and Yang31, Th. 3.6]. Then, the silting reduction [Reference Iyama and Yang31, Th. 3.6] shows that there is a triangle equivalence between $\mathcal {T}/\mathcal {S}$ and $\frac {\mathcal {Z}}{[S]}$ . Since $\mathcal {T}$ is Hom-finite and Krull–Schmidt, so is $\mathcal {T}/\mathcal {S}$ .
Now, we prepare a lemma for the main theorem of this subsection.
Lemma 2.12. Keep the notations above. If $\mathcal {T}$ is silting-discrete, then so is $\mathcal {T}/\mathcal {S}$ .
Proof. By the silting reduction [Reference Iyama and Yang31, Th. 3.7 and Cor. 3.8], the natural functor $\mathcal {T}\to \mathcal {T}/\mathcal {S}$ induces an isomorphism $\operatorname {\mathsf {silt}}_S\mathcal {T}\simeq \operatorname {\mathsf {silt}}\mathcal {T}/\mathcal {S}$ of posets. Thus, it is not hard to deduce that $\mathcal {T}/\mathcal {S}$ is silting-discrete.
Remark 2.13. We are assuming that $\operatorname {\mathsf {silt}}\mathcal {T}\neq \emptyset $ to apply the silting reduction, while $\operatorname {\mathsf {silt}}\mathcal {T}/\mathcal {S}=\emptyset $ may occur (see §B.2).
To realize the goal of this subsection, we need (nonpositive) dg algebras.
Let $\mathcal {A}$ be a dg K-algebra and $\operatorname {\mathsf {per}}(\mathcal {A})$ denote the perfect derived category of $\mathcal {A}$ . If $\mathcal {A}$ is nonpositive with finite-dimensional cohomologies, then $\operatorname {\mathsf {per}}(\mathcal {A})$ is Hom-finite and Krull–Schmidt (see, e.g., [Reference Adachi, Mizuno and Yang4, Prop. 6.12]).
We give a remarkable example [Reference Yang55, Exam. 5.3], which mentions that the zeroth cohomology $H^0(\mathcal {A})$ of $\mathcal {A}$ does not necessarily inherit the silting-discreteness from $\mathcal {A}$ ; moreover, the endomorphism algebra of a silting object does not always inherit the property either.
Example 2.14. Let $\Lambda $ be the algebra presented by the quiver Q
with relation $\alpha \beta \gamma =0$ . Then, we easily observe that $\Lambda $ is piecewise hereditary of type $E_6$ ; so, it is silting-discrete. Take $T:=S_1\oplus S_2[1]\oplus S_3[2]\oplus S_4[3]\oplus S_5[2]\oplus S_6[1]$ , where $S_i$ is the simple module corresponding to the vertex i of Q; it is in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ because $\Lambda $ has finite global dimension. We see that T is a silting object whose dg endomorphism algebra $\mathcal {A}$ is nonpositive with finite-dimensional cohomologies; so, $\operatorname {\mathsf {per}}(\mathcal {A})$ is Krull–Schmidt. By Keller–Rickard’s theorem [Reference Keller36], [Reference Rickard48], we have a triangle equivalence $\operatorname {\mathsf {per}}(\mathcal {A})\simeq \mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ , whence $\operatorname {\mathsf {per}}(\mathcal {A})$ is silting-discrete. However, the zeroth cohomology $H^0(\mathcal {A})$ of $\mathcal {A}$ , which is isomorphic to $\operatorname {End}_{\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )}(T)$ , is the radical-square-zero algebra of $Q^{\mathrm {op}}$ , and it is derived equivalent to a hereditary algebra of type $\widetilde {D_5}$ . Thus, $H^0(\mathcal {A})$ is not silting-discrete.
This example also says that although a derived preprojective algebra $\mathcal {A}$ of Dynkin type (it is a nonpositive dg algebra) admits a silting-discrete perfect derived category [Reference Adachi, Mizuno and Yang4, Cor. 8.6], it is still open whether a preprojective algebra of Dynkin type except $A_2, D_{2n}, E_7$ , and $E_8$ , which appears as the zeroth cohomology of $\mathcal {A}$ , is silting-discrete or not.
We aim at our goal of this subsection.
Recall that a recollement $\mathcal {R}$ consists of the following data of triangulated categories $\mathcal {D}, \mathcal {X}$ , and $\mathcal {Y}$ , and triangle functors between them:
such that:
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(1) $(i^{*}, i_*),\ (i_!, i^!),\ (j_!, j^!)$ , and $(j^{*}, j_*)$ are adjoint pairs;
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(2) $i_*\ (=i_!),\ j_!$ , and $j_*$ are fully faithful;
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(3) any object D of $\mathcal {D}$ admits two triangles
$$\begin{align*}\begin{array}{c@{\ \mbox{and }}c} i_!i^!(D)\to D\to j_*j^{*}(D)\to i_!i^!(D)[1] & j_!j^!(D)\to D\to i_*i^{*}(D)\to j_!j^!(D)[1], \end{array}\end{align*}$$where the morphisms around D are given by adjunctions.
Omitting the triangle functors, we write such a recollement as $\mathcal {R}=(\mathcal {Y}, \mathcal {D}, \mathcal {X})$ .
We denote by $\operatorname {\mathsf {D}}(-)$ the (unbounded) derived category, and for an object X of $\operatorname {\mathsf {D}}(\Lambda )$ , $\operatorname {\mathsf {Tria}}(X)$ stands for the smallest full triangulated subcategory of $\operatorname {\mathsf {D}}(\Lambda )$ containing X which is closed under all direct sums.
From now, we consider either of the following situations.
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• Start from a given recollement $(\mathcal {Y}, \operatorname {\mathsf {D}}(\Lambda ),\mathcal {X})$ with $\mathcal {X}$ compactly generated: Then, by [Reference Angeleri-Hugel, Marks and Vitoria12, Th. 4.5], $\mathcal {X}$ can be written as $\operatorname {\mathsf {Tria}}(S)$ for some presilting object S of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ .
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• Start from a given presilting object S of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ : Since $\operatorname {\mathsf {Tria}}(S)$ is a smashing subcategory of $\operatorname {\mathsf {D}}(\Lambda )$ [Reference Angeleri-Hugel, Marks and Vitoria12, Prop. 3.5], there exists a full triangulated subcategory $\mathcal {Y}$ of $\operatorname {\mathsf {D}}(\Lambda )$ such that $(\mathcal {Y}, \operatorname {\mathsf {D}}(\Lambda ), \operatorname {\mathsf {Tria}}(S))$ forms a recollement; actually, $\mathcal {Y}$ is right perpendicular to $\operatorname {\mathsf {Tria}}(S)$ [Reference Nicolas and Saorin44, Cor. 2.4].
In any case, we have a recollement $(\mathcal {Y},\operatorname {\mathsf {D}}(\Lambda ),\operatorname {\mathsf {Tria}}(S))$ for a presilting object S of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . Furthermore, thanks to Nicolas–Saorin’s result [Reference Nicolas and Saorin44, §4], there is a dg K-algebra $\mathcal {A}$ and a morphism $\varphi :\Lambda \to \mathcal {A}$ of dg algebras such that $i_!=-\otimes ^{\mathsf {L}}_{\mathcal {A}}\mathcal {A}$ induces a recollement $(\operatorname {\mathsf {D}}(\mathcal {A}), \operatorname {\mathsf {D}}(\Lambda ),\operatorname {\mathsf {Tria}}(S))$ . Here, $\varphi $ is embedded into the triangle $X:=\operatorname {\mathsf {RHom}}_\Lambda (S, \Lambda )\otimes ^{\mathsf {L}}_{\mathcal {B}} S\to \Lambda \xrightarrow {\varphi }\mathcal {A}\to X[1]$ in $\operatorname {\mathsf {D}}(\Lambda ^{\mathrm {op}}\otimes _K\Lambda )$ , where $\mathcal {B}$ is the dg endomorphism algebra of S. We evidently observe that $H^i(\mathcal {A})$ is finite-dimensional for any i. One can also describe $\mathcal {A}$ as the dg endomorphism algebra of $\Lambda $ in a dg enhancement of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )/\operatorname {\mathsf {thick}}(S)$ . Such a morphism $\varphi $ is called a homological epimorphism (see [Reference Pauksztello46]).
Now, we state the second main theorem of this paper.
Theorem 2.15. Keep the notations above. If $\Lambda $ is silting-discrete, then so is $\operatorname {\mathsf {per}}(\mathcal {A})$ .
A key point is an analog of the proof of [Reference Kalck and Yang33, Cor. 2.12(a)].
Proof. The recollement $(\operatorname {\mathsf {D}}(\mathcal {A}), \operatorname {\mathsf {D}}(\Lambda ), \operatorname {\mathsf {Tria}}(S))$ as in before Theorem 2.15 gives rise to an exact sequence $0\to \operatorname {\mathsf {Tria}}(S)\to \operatorname {\mathsf {D}}(\Lambda )\xrightarrow {i^{*}}\operatorname {\mathsf {D}}(\mathcal {A})\to 0$ of triangulated categories. As S is presilting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ , we derive from the Thomason–Trobaugh–Yao localization theorem [Reference Neeman43, Th. 2.1] that $i^{*}$ induces a triangle equivalence $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )/\operatorname {\mathsf {thick}}(S)\simeq \operatorname {\mathsf {per}}(\mathcal {A})$ , whence $\operatorname {\mathsf {per}}(\mathcal {A})$ is silting-discrete by Lemma 2.12.
Remark 2.16. Theorem 2.15 holds enough for a nonpositive dg K-algebra $\Lambda $ .
The proof of Theorem 2.15 spins off the following result, which mentions a Bongartz-type lemma for a given presilting object S; if $\Lambda \geq S\geq \Lambda [1]$ , then $\mathcal {A}$ is nonpositive because $H^i(\mathcal {A})\simeq H^{i+1}(X)$ , so the result gives a generalization of Proposition 2.5(1).
Corollary 2.17. Keep the notations as in before Theorem 2.15. Assume that $\mathcal {A}$ is nonpositive. Then S is partial silting.
Proof. In the proof of Theorem 2.15, we got a triangle equivalence $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )/\operatorname {\mathsf {thick}} S\simeq \operatorname {\mathsf {per}}(\mathcal {A})$ . The silting reduction (Lemma 2.12) yields isomorphisms $\operatorname {\mathsf {silt}}_S(\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda ))\simeq \operatorname {\mathsf {silt}}(\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )/\operatorname {\mathsf {thick}} S)\simeq \operatorname {\mathsf {silt}}(\operatorname {\mathsf {per}}(\mathcal {A}))$ of posets. Since $\mathcal {A}$ is nonpositive, it is silting in $\operatorname {\mathsf {per}}(\mathcal {A})$ , whence $\operatorname {\mathsf {silt}}(\operatorname {\mathsf {per}}(\mathcal {A}))$ is nonempty; so is $\operatorname {\mathsf {silt}}_S(\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda ))$ . Thus, it turns out that S is partial silting.
Let e be an idempotent of $\Lambda $ . Following [Reference Kalck and Yang33, Prop. 2.10] and its proof, we can construct a nonpositive dg K-algebra $\mathcal {A}_e$ and a homological epimorphism $\varphi :\Lambda \to \mathcal {A}_e$ of dg algebras; embed the canonical morphism $\Lambda e\otimes ^{\mathsf {L}}_{e\Lambda e}e\Lambda \to \Lambda $ into the triangle
and take the standard truncations $\mathcal {A}_e:=\sigma ^{\leq 0}(\mathcal {A}')$ and $\varphi :=\sigma ^{\leq 0}(\varphi ')$ , where for a complex $(X^i, d^i)$ , the standard truncation $\sigma ^{\leq 0}(X)$ is the complex $\cdots \to X^{-1}\to \operatorname {Ker} d^0\to 0$ . Then, $\mathcal {A}_e$ and $\varphi $ are the desired dg algebra and homological epimorphism, since we have isomorphisms
Here is a corollary of Theorem 2.15 and Corollary 2.17.
Corollary 2.18. Let e be an idempotent of $\Lambda $ . Then we have the following.
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(1) If $\Lambda $ is silting-discrete, then so is $\operatorname {\mathsf {per}}(\mathcal {A}_e)$ .
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(2) A presilting object of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ generating $\operatorname {\mathsf {thick}}(e\Lambda )$ is partial silting.
Proof. As above, we obtain a recollement $(\operatorname {\mathsf {D}}(\mathcal {A}_e), \operatorname {\mathsf {D}}(\Lambda ), \operatorname {\mathsf {Tria}}(e\Lambda ))$ and know that $\mathcal {A}_e$ is nonpositive. So, the first assertion directly follows from Theorem 2.15. If S is a presilting object of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ generating $\operatorname {\mathsf {thick}}(e\Lambda )$ , then we have $\operatorname {\mathsf {Tria}}(S)=\operatorname {\mathsf {Tria}}(e\Lambda )$ , whence the last assertion is derived from Corollary 2.17.
We remark that Corollary 2.18(2) can be shown more directly by the silting reduction. That is, let $\mathcal {S}:=\operatorname {\mathsf {thick}} S$ , then $\mathcal {S}=\operatorname {\mathsf {thick}} e\Lambda $ by assumption, and so the silting reduction yields isomorphisms $\operatorname {\mathsf {silt}}_S\Lambda \simeq \operatorname {\mathsf {silt}}\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )/\mathcal {S}\simeq \operatorname {\mathsf {silt}}_{e\Lambda }\Lambda $ of posets. As the last set is nonempty (because $\Lambda $ is the member), we have $\operatorname {\mathsf {silt}}_S\Lambda \neq \emptyset $ , whence S is partial silting.
In the rest of this subsection, we give an explicit description of $\mathcal {A}_e$ and its example thanks to [Reference Kalck and Yang35].
We first construct a nonpositive dg algebra $\widetilde {\Lambda }$ quasi-isomorphic to $\Lambda $ (i.e., $H^i(\widetilde {\Lambda })\simeq H^i(\Lambda )$ ; see [Reference Oppermann45, Construction 2.6]). Let $\Lambda $ be presented by a (finite) quiver Q with admissible ideal I; write $Q^{(0)}:=Q$ . We make a graded quiver $Q^{(1)}$ by adding to $Q^{(0)}$ arrows in degree $-1$ which correspond to each element of I and consider a differential which sends new arrows to their corresponding relations; then $H^0(KQ^{(1)})=\Lambda $ . Picking out a generating set of $H^{-1}(KQ^{(1)})$ , one produces a graded quiver $Q^{(2)}$ by adding to $Q^{(1)}$ arrows in degree $-2$ which correspond to each element of the generating set and consider a differential as well. Iterating this, we get a graded quiver $Q^{(\infty )}:=\bigcup _{i=0}^\infty Q^{(i)}$ such that the dg quiver algebra $\widetilde {\Lambda }:=(KQ^{(\infty )}, d)$ is quasi-isomorphic to $\Lambda $ .
Now, we apply Theorem 7.1 of [Reference Kalck and Yang35] to obtain that $\mathcal {A}_e$ is quasi-isomorphic to $\widetilde {\Lambda }/\widetilde {\Lambda }\widetilde {e}\widetilde {\Lambda }$ , where $\widetilde {e}$ is the idempotent of $\widetilde {\Lambda }$ corresponding to e.
Example 2.19. Let $\Lambda $ be the algebra presented by the quiver
with $\beta \gamma =0$ ; it is silting-discrete by Proposition 2.8. Then, $\widetilde {\Lambda }$ is the dg quiver algebra of
with $\deg (\delta )=-1$ , the other arrows are of degree 0 and with the trivial differential.
Let e be the primitive idempotent of $\Lambda $ corresponding to the vertex 3. We see that $\mathcal {A}_e$ is the dg quiver algebra of the graded Kronecker quiver with arrows of degrees 0 and $-1$ , and the trivial differential. This is silting-discrete by Corollary 2.18(1).
Note that the dg quiver algebra of the graded Kronecker quiver with arrows of the same degree $n\leq 0$ and the trivial differential is not silting-discrete; indeed, it is derived equivalent to the (ordinary) Kronecker algebra . Here, $P_1$ and $P_2$ are the indecomposable projective modules corresponding to the vertices 1 and 2, respectively.
This observation gives an example of silting-indiscrete algebras.
Example 2.20. Let Q be the quiver of type $\widetilde {A_{p,q}}$ ( $p,q\geq 2$ ); assign to the arrows of two paths (resp. length p and q) from the source to the sink $\alpha $ and $\beta $ , respectively. Then $\Lambda :=KQ/(\alpha ^p, \beta ^q)$ is silting-indiscrete.
Proof. We see that $\widetilde {\Lambda }$ is given by the graded quiver
with the dashed arrows of degree $-1$ . Taking the sum e of the primitive idempotents of $\Lambda $ corresponding to all but the vertices 1 and 2, it is obtained that $\widetilde {\Lambda }/\widetilde {\Lambda }\widetilde {e}\widetilde {\Lambda }$ is the dg quiver algebra of the graded Kronecker quiver with arrows of degree $-1$ , which is silting-indiscrete, so is $\Lambda $ by Corollary 2.18(1).
2.3. Homological epimorphisms of algebras
In this subsection, we restrict the results in §2.2 to ordinary algebras; that is, $\mathcal {A}$ is just an algebra.
Let $\Gamma $ be a finite-dimensional K-algebra. Recall that a homomorphism $\varphi :\Lambda \to \Gamma $ of algebras is a homological epimorphism if the canonical morphism $\Gamma \otimes ^{\mathsf {L}}_\Lambda \Gamma \to \Gamma $ is an isomorphism in the derived category of $(\Gamma , \Gamma )$ -bimodules; that is, the multiplication map $\Gamma \otimes _\Lambda \Gamma \to \Gamma $ is isomorphic and $\operatorname {Tor}^\Lambda _i(\Gamma ,\Gamma )=0$ for all $i>0$ . Note that the former condition $\Gamma \otimes _\Lambda \Gamma \simeq \Gamma $ is satisfied if and only if $\varphi $ is an epimorphism in the category of rings; it is called a ring-epimorphism [Reference Silver51, Prop. 1.1]. A surjective homomorphism (i.e., an ordinary epimorphism) is a ring-epimorphism, but the converse is not always true.
As a homological epimorphism $\Lambda \to \Gamma $ of algebras induces a recollement $(\operatorname {\mathsf {D}}(\Gamma ), \operatorname {\mathsf {D}}(\Lambda ), \mathcal {X})$ by [Reference Nicolas and Saorin44, §4], we immediately obtain the following result from Theorem 2.15 under a subtle condition.
Corollary 2.21. Let $\varphi :\Lambda \to \Gamma $ be a homological epimorphism and assume that $\mathcal {X}$ is compactly generated; for example, the projective dimension of the right $\Lambda $ -module $\Gamma _\Lambda $ is finite. If $\Lambda $ is silting-discrete, then so is $\Gamma $ .
We say that an idempotent e of $\Lambda $ (or the ideal $\Lambda e\Lambda $ ) is stratifying if the canonical homomorphism $\pi :\Lambda \to \Lambda /\Lambda e\Lambda $ is a homological epimorphism; equivalently, the dg algebra $\mathcal {A}_e$ as in Corollary 2.18 is just isomorphic to $\Lambda /\Lambda e\Lambda $ . For example, if $\Lambda $ is hereditary (i.e., $\Lambda =KQ$ for an acyclic quiver Q), then any idempotent e of $\Lambda $ is stratifying; notice that $\widetilde {\Lambda }$ as in the last of §2.2 is nothing but $(KQ, 0)=\Lambda $ . More generally, if $\Lambda e\Lambda $ is projective as a right $\Lambda $ -module, then it is stratifying. Here is a direct consequence of Corollaries 2.18/2.21.
Corollary 2.22. Let e be a stratifying idempotent of $\Lambda $ . If $\Lambda $ is silting-discrete, then so is $\Lambda /\Lambda e\Lambda $ .
A typical example of stratifying idempotents is a primitive idempotent corresponding to a source or a sink in the Gabriel quiver of $\Lambda $ . So, we have:
Example 2.23. Let e be a primitive idempotent corresponding to a source or a sink in the Gabriel quiver of $\Lambda $ . If $\Lambda $ is silting-discrete, then so is $\Lambda /\Lambda e\Lambda $ . In other words, if a one-point extension algebra of $\Lambda $ is silting-discrete, then so is $\Lambda $ .
We remark that this example can also be got from the fact that $\Lambda /\Lambda e\Lambda $ is isomorphic to $(1-e)\Lambda (1-e)$ for such an idempotent e.
Note that the converse of Example 2.23 does not necessarily hold; a one-point extension of a path algebra of Dynkin type is often of non-Dynkin type. This also means that the silting-discreteness of both sides in a recollement is not always passed to the middle in the recollement.
We apply Example 2.23 to tree quiver algebras.
Example 2.24. Let $\Lambda $ be a tree quiver algebra; that is, the underlying graph of its Gabriel quiver is a tree. If $\Lambda $ is silting-discrete, then so is $\Lambda /\Lambda e\Lambda $ for every idempotent e of $\Lambda $ .
2.4. Remark on Kronecker algebras
As is well-known, the Kronecker algebras are a first and good example of $\tau $ -tilting infinite algebras. When we discuss silting-discreteness, one often needs graded Kronecker algebras, as we already observed in the preceding subsections. Now, we summarize it.
Let $\mathcal {K}$ be the dg quiver algebra of a graded n-Kronecker quiver with trivial differential. For $\lambda :=(n_i)_i\in \bigoplus _{i\in \mathbb {Z}}\mathbb {Z}_{\geq 0}$ , we write $\mathcal {K}:=\mathcal {K}(\lambda )$ , where $n_i$ stands for the number of arrows of degree i; we will omit the zero parts. Note that $n=\sum _i n_i$ . We remark that applying shifts, $\mathcal {K}((n_i)_i)$ is derived equivalent to $\mathcal {K}((n_{i+m})_i)$ for every $m\in \mathbb {Z}$ .
In case that $n_i\neq 0$ for at most two components i, we get the following result.
Proposition 2.25. Let $i<0$ . Then $\mathcal {K}=\mathcal {K}(n_0, n_i)$ is silting-discrete if and only if $n_0, n_i\leq 1$ .
Proof. If $n_0\geq 2$ , then $H^0(\mathcal {K})$ is the ordinary (2-)Kronecker algebra; so, it is not $\tau $ -tilting finite. Therefore, $\mathcal {K}$ is not silting-discrete. Let $n_i\geq 2$ and $S:=H^0(\mathcal {K})/\operatorname {rad} H^0(\mathcal {K})$ . Then the Koszul dual $\mathcal {K}^!:=\operatorname {Ext}_{\mathcal {K}}^{*}(S, S)$ of $\mathcal {K}$ is quasi-isomorphic to $\mathcal {K}(n^{\prime }_{1-i}, n^{\prime }_1)$ , which is derived equivalent to $\mathcal {K}(n^{\prime \prime }_0, n^{\prime \prime }_i)$ . Here, $n^{\prime \prime }_0=n^{\prime }_{1-i}=n_i$ and $n^{\prime \prime }_i=n^{\prime }_1=n_0$ . Since $\mathcal {K}$ and $\mathcal {K}^!$ are derived equivalent [Reference Su and Yang52, §5], we obtain that $\mathcal {K}$ is not silting-discrete.
Let us show the if part; we only handle the case that $n_0=1=n_i$ . Let $\Lambda $ be the radical-square-zero algebra given by the quiver
It follows from Proposition 2.8 that $\Lambda $ is silting-discrete. Let $e_v$ be the primitive idempotent of $\Lambda $ corresponding to the vertex v. Taking the idempotent $e:=e_1+\cdots +e_{-i}$ , we see that $\mathcal {K}$ is quasi-isomorphic to $\mathcal {A}_e$ , whence it is silting-discrete by Corollary 2.18.
Remark 2.26. We know from [Reference Liu and Yang41, Cor. 3.2] that if $\mathcal {K}$ is derived equivalent to an ordinary algebra, then $\mathcal {K}=\mathcal {K}(n_0, n_{-1})$ up to shift. Moreover, by [Reference Liu and Yang41, Cor. 3.10], it is seen that $\mathcal {K}(n_0, n_{-1})$ is derived equivalent to the algebra presented by the quiver consisting of vertices 1 and 2 with $n_0$ arrows from 1 to 2 (say x) and $n_{-1}$ arrows from 2 to 1 (say y), and with all relations $yx=0$ . This is just a quasi-hereditary algebra with two simples.
Remark 2.27. We observe that $\mathcal {K}(1,1)$ for an arbitrary degree is derived equivalent to a graded gentle one-cycle algebra, which behaves like (ordinary) derived-discrete algebras. We hope that graded gentle one-cycle algebras which are not derived equivalent to $K\widetilde {A}$ are silting-discrete (see [Reference Kalck and Yang34]).
2.5. Remark on quotients
We give a remark on the inheritance of silting-discreteness by (idempotent) quotients, comparing with $\tau $ -tilting finiteness.
First, note that algebra (ordinary) epimorphisms cannot necessarily transmit the silting-discreteness (see Proposition 2.9 and Example 2.20).
Next, let us observe that idempotent quotients cannot always inherit the silting-discreteness, either. Let $\Gamma $ be the algebra given by the quiver
with relations $\beta \alpha =\delta \alpha =\gamma \varepsilon =0$ and $\gamma \beta =yx$ . To check that $\Gamma $ is a piecewise hereditary algebra of type $E_7$ , we first show the following claim.
Claim. Let $\Lambda $ be a piecewise hereditary algebra of Dynkin type and M an indecomposable right $\Lambda $ -module. Then the one-point extension algebra $\begin {pmatrix} K & M \\ 0 & \Lambda \end {pmatrix}$ is derived equivalent to a hereditary algebra.
Proof. Let A be a hereditary algebra of Dynkin type which is derived equivalent to $\Lambda $ . Applying shift functors if needed, we may assume that M corresponds to an indecomposable A-module N under a derived equivalence between $\Lambda $ and A. Since A is representation-finite, there is an integer $\ell \geq 0$ with $P:=\tau ^\ell (N)$ projective. Here, $\tau $ denotes the Auslander–Reiten translation. As it induces a derived autoequivalence of A, we can take a derived equivalence between $\Lambda $ and A which sends M to P. By [Reference Barot and Lenzing18, Th. 1], we obtain that $\begin {pmatrix} K & M \\ 0 & \Lambda \end {pmatrix}$ is derived equivalent to $\begin {pmatrix} K & P \\ 0 & A \end {pmatrix}$ , which is hereditary.
We recall the definitions of the Coxeter matrix, Coxeter polynomial, and spectral radius of a hereditary algebra $\Lambda $ . Let C be the Cartan matrix of $\Lambda $ . Then the matrix $-C^{-1}C^t$ and its characteristic polynomial are called the Coxeter matrix and the Coxeter polynomial of $\Lambda $ , respectively. Here, $C^t$ denotes the transpose of C. Let $\alpha _1, \ldots , \alpha _n$ be the eigenvalues of the Coxeter matrix; that is, the complex roots of the Coxeter polynomial. The spectral radius of $\Lambda $ is defined to be the maximum of the absolute values of $\alpha _i$ ’s.
Let us return our attention to $\Gamma $ . Since the full subquiver with the vertices 2, 3, 4, and 7 makes a piecewise hereditary algebra of type $D_4$ , we observe by the claim that the one-point extension at the vertex 5 is derived equivalent to a hereditary algebra whose Coxeter polynomial is $(x+1)(x^4+1)$ , which is of type $D_5$ . Therefore, it turns out that the algebra presented by the full subquiver with the vertices 2, 3, 4, 5, and 7 is piecewise hereditary of type $D_5$ . As a similar argument (use the dual of the claim), we see that $\Gamma $ is derived equivalent to a hereditary algebra with Coxeter polynomial $(x+1)(x^6-x^3+1)$ , which is of type $E_7$ . Thus, we figure out that $\Gamma $ is silting-discrete.
However, it is obtained by Example 2.14 that the idempotent quotient $\Gamma /\Gamma e_7\Gamma $ is not silting-discrete, where $e_7$ denotes the primitive idempotent corresponding to the vertex 7.
Remark 2.28. Although Coxeter polynomials are a derived invariant, we cannot judge the silting-discreteness of a given algebra only by them, in general. Actually, the extended canonical algebra of type $\langle 2,4,6 \rangle $ , which is given by the quiver
with relation $z^6=x^2-y^4$ , has the same Coxeter polynomial as a (piecewise) hereditary algebra of type $D_{12}$ [Reference Lenzing and de la Pena39, Prop. 5.9], but it is not silting-discrete. Note that the algebra is never derived equivalent to a hereditary algebra; for a hereditary algebra, if the spectral radius ( $=1$ ) is not a root of the Coxeter polynomial, then the algebra is representation-finite; if the spectral radius ( $=1$ ) is a root of the Coxeter polynomial, then the algebra is representation-tame; if the spectral radius is strictly greater than 1, then the algebra is representation-wild.
3. Applications
In this section, we investigate the silting-discreteness of finite-dimensional algebras; in particular, we focus on
Let $\Lambda $ be a finite-dimensional K-algebra which is basic and ring-indecomposable. Let $\overrightarrow {A_n}$ be the quiver . For two successive arrows in the Gabriel quiver of $\Lambda $ , we draw if $\alpha \beta =0$ .
3.1. Simply connected tensor algebras
In this subsection, we completely classify silting-discrete simply connected tensor algebras. Since we already know that the tensor algebra of three nonlocal algebras is nothing but not silting-discrete [Reference Aihara and Honma7, Prop. 4.1], one turns the interest to the classification of silting-discrete simply connected tensor algebras of two algebras. Here is the first case; one of the two is K.
Proposition 3.1. A simply connected algebra is silting-discrete if and only if it is piecewise hereditary of Dynkin type.
Proof. The if part is trivial. We show the only if part. Let $\Lambda $ be a silting-discrete simply connected algebra. Note that the silting-discreteness implies the $2_\Lambda $ -silting finiteness (the $\tau $ -tilting finiteness for $\Lambda $ ). We see by [Reference Wang54, Th. 3.4] that $\Lambda $ is representation-finite. Since $\Lambda $ is silting-discrete, any reflection of $\Lambda $ is $\tau $ -tilting finite. Moreover, it follows from [Reference Assem, Nehring and Skowronski14, Lem. 3.1] that every reflection of $\Lambda $ is simply connected, so it is representation-finite. Then, we apply Proposition 3.3 of [Reference Assem, Nehring and Skowronski14] to deduce that the repetitive algebra of $\Lambda $ is locally representation-finite, which implies that it is piecewise hereditary of Dynkin type by [Reference Happel28].
In the rest of this subsection, let A and B be triangular algebras which are basic and ring-indecomposable, and put $\Lambda :=A\otimes _KB$ . Here, a triangular algebra is a finite-dimensional K-algebra whose Gabriel quiver is acyclic.
Our goal of this subsection is to give a complete classification of silting-discrete simply connected tensor algebras. We know that $\Lambda $ is silting-discrete if A is local and B is silting-discrete [Reference Aihara and Honma7, Th. 2.1]. Let us give an easy observation.
Lemma 3.2. If $\Lambda $ is silting-discrete, then so are both A and B.
Proof. Let e be a primitive idempotent of A. As A is triangular, we have an isomorphism $eAe\simeq K$ . Apply Corollary 2.11 to deduce that $B\simeq (e\otimes 1)\Lambda (e\otimes 1)$ is silting-discrete.
We determine the algebra structure of one of the components when $\Lambda $ is silting-discrete.
Lemma 3.3. If $\Lambda $ is silting-discrete, then at least one of A and B has at most two nonisomorphic simple modules. In particular, it is isomorphic to K or $K\overrightarrow {A_2}$ .
Proof. By Lemma 3.2, it is observed that A and B are silting-discrete, and so they have no multiple arrow in their Gabriel quivers [Reference Demonet, Iyama, Reading, Reiten and Thomas26, Th. 5.12(d)]. Note that for every idempotent e of A, $eAe$ is a silting-discrete triangular algebra.
Now, assume that A has at least three nonisomorphic simple modules. As above, there exists an idempotent e of A such that $eAe$ is isomorphic to one of the following:
From Corollary 2.11, we obtain that $(e\otimes 1)\Lambda (e\otimes 1)=(eAe)\otimes _KB$ is silting-discrete. Note that the first two of the three algebras above are derived equivalent to the path algebra $K\overrightarrow {A_3}$ . If $eAe$ is one of the first two, then $(eAe)\otimes _KB$ is derived equivalent to $K\overrightarrow {A_3}\otimes _KB$ , which must be silting-discrete. This yields by [Reference Aihara and Honma7, Th. 4.4] that B is a Nakayama algebra with radical square zero, whence it is isomorphic to $K\overrightarrow {A_r}/\operatorname {rad}^2K\overrightarrow {A_r}$ for some $r>0$ ; because B is triangular. We see that $(eAe)\otimes _KB$ is derived equivalent to $K\overrightarrow {A_3}\otimes _KK\overrightarrow {A_r}$ , which is also silting-discrete. By [Reference Aihara and Honma7, Th. 4.4] again, we have $r\leq 2$ .
Finally, let us suppose that $eAe$ is the last of the three algebras above, which is derived equivalent to the algebra C given by the quiver
with $\gamma \beta =0$ . So, we observe that $(eAe)\otimes _KB$ is derived equivalent to $C\otimes _KB$ , which is silting-discrete. Since there is an epimorphism $C\otimes _KB\to K\overrightarrow {A_3}\otimes _KB$ , it turns out that $K\overrightarrow {A_3}\otimes _KB$ is $\tau $ -tilting finite [Reference Demonet, Iyama, Reading, Reiten and Thomas26]. As a similar argument above, we conclude that B has at most two nonisomorphic simple modules.
We often call the algebra $K\overrightarrow {A_2}\otimes _KK\overrightarrow {A_r}$ the commutative ladder of degree r, which is presented by the quiver with relations as follows:
Now, we realize the goal of this subsection, which gives a complete classification of silting-discrete simply connected tensor algebras.
Theorem 3.4. Assume that A and B are nonlocal and simply connected. Then the following are equivalent:
-
(1) $\Lambda $ is silting-discrete.
-
(2) It is a piecewise hereditary algebra of type $D_4, E_6$ , or $E_8$ .
-
(3) It is derived equivalent to the commutative ladder of degree $\leq 4$ .
Note that the case of $\Lambda $ being a piecewise hereditary algebra of type $A_2$ cannot occur since if so, then either A or B is local.
Proof. The equivalence (2) $\Leftrightarrow $ (3) is due to [Reference Ladkani38]. We know the implication (2) $\Rightarrow $ (1) holds. Let us show the implication (1) $\Rightarrow $ (3) holds true. Applying Lemma 3.3, we may suppose that $A\simeq K\overrightarrow {A_2}$ . By Lemma 3.2, one sees that B is silting-discrete. Therefore, it follows from Proposition 3.1 that B is piecewise hereditary of Dynkin type $\Delta $ , whence $\Lambda $ is derived equivalent to $K\overrightarrow {A_2}\otimes _KK\overrightarrow {\Delta }$ . Since this is silting-discrete, we observe that $\Delta $ must be of type $A_r$ by [Reference Aihara and Honma7, Th. 3.2]; that is, $\Lambda $ is derived equivalent to the commutative ladder of degree r. By [Reference Aihara and Honma7, Exam. 3.3], we get $r\leq 4$ .
Remark 3.5. Lemma 3.3 also says that if $\Lambda $ is silting-discrete, then at least one of A and B is automatically simply connected. Then, we ask whether they both are simply connected or not. In fact, it seems to be unknown that $K\overrightarrow {A_2}\otimes _KC$ is silting-discrete, where C is the algebra presented by the quiver with relation:
(It is $\tau $ -tilting finite, thanks to Aoki’s QPA program.) This is also one reason why we cannot drop the assumption of A and B being simply connected in Theorem 3.4.
3.2. Self-injective Nakayama algebras
Ten years ago, the first-named author of this paper showed that any representation-finite symmetric algebra is silting-discrete [Reference Aihara5]. Then, we might naturally hope that every representation-finite self-injective algebra is also silting-discrete. However, we here give the following surprising result, which says that the guess does not necessarily hold.
Theorem 3.6. Let $\Lambda $ be a (nonlocal) self-injective Nakayama algebra; that is, it is presented by the cyclic quiver with n vertices, and the rth radical is zero for some $n, r>1$ . Then $\Lambda $ is not silting-discrete if (i) $r=3, 4$ and $n\geq 11$ ; (ii) $r=5,6$ and $n\geq r+8$ ; or (iii) $r\geq 7$ and $n\geq 2r+1$ .
Let $n,r>1$ . We denote by $N_{n,r}$ the algebra given by the quiver
with $x^r=0$ . The primitive idempotent corresponding to the vertex i of the quiver is denoted by $e_i$ . As is well-known, an algebra is a nonlocal self-injective (symmetric) Nakayama algebra if and only if it is isomorphic to $N_{n, r}$ for some $n,r>1$ ( $r\equiv 1\pmod n$ ).
We give an example of silting-discrete self-injective Nakayama algebras.
Proposition 3.7. If $r=2$ or $r\equiv 1\,\pmod n$ , then $N_{n,r}$ is silting-discrete.
Proof. By Proposition 2.8 for $r=2$ and [Reference Aihara5, Th. 5.6] for $r\equiv 1\,\pmod n$ .
Put $A(n,r):=K\overrightarrow {A_n}/\operatorname {rad}^r K\overrightarrow {A_n}$ . Under a suitable condition, we can get $A(n,r)$ by an idempotent truncation of a self-injective Nakayama algebra.
Lemma 3.8. Let $1\leq s\leq n$ and put $e:=e_1+\cdots +e_s$ . If $s+r\leq n+1$ , then $eN_{n,r}e$ is isomorphic to $A(s,r)$ .
Proof. Straightforward.
Thanks to the list of [Reference Happel and Seidel29] (see also [Reference Lenzing and de la Pena39]), we give a complete classification.
Lemma 3.9.
-
(1) If $A(s,r)$ is not silting-discrete, then neither is $A(s+1, r)$ .
-
(2) $A(s,r)$ is silting-discrete if and only if one of the following cases occurs:
-
(i) $r=2$ ;
-
(ii) $r=3, 5, 6$ and $s\leq 8$ ;
-
(iii) $r=4$ and $s\leq 7$ ;
-
(iv) $r\geq 7$ and $s=r+1$ .
-
Proof. (1) Apply Corollary 2.11 to $A(s, r)\simeq (1-e_{s+1})A(s+1, r)(1-e_{s+1})$ .
(2) For each r, the list of Happel–Seidel (Table 1) describes a border of s for which $A(s, r)$ is derived equivalent to a hereditary algebra of Dynkin type or not. Then, by (1), we completely understand whether $A(s, r)$ is silting-discrete or not. For instance, when $r\geq 7$ , $A(r+2, r)$ is derived equivalent to a path algebra of type $T_{23(r-1)}$ ( $\widetilde {E_8}=T_{236}$ ), which is not Dynkin; so, it is silting-indiscrete.
Now, we show the main theorem of this subsection.
Proof of Theorem 3.6
Let $\Lambda :=N_{n,r}$ for $n,r>1$ . We put s in each case as follows:
-
(i) $r=3,4$ and $n\geq 11\rightsquigarrow s=9\ (r=3)$ or $s=8\ (r=4)$ .
-
(ii) $r=5,6$ and $n\geq r+8\rightsquigarrow s=9$ .
-
(iii) $r\geq 7$ and $n\geq 2r+1\rightsquigarrow s=r+2$ .
In all the cases, the assumption of Lemma 3.8 is satisfied; hence, $e\Lambda e\simeq A(s,r)$ .
By Lemma 3.9, we see that $A(s,r)$ is not silting-discrete for these pairs $(s,r)$ , whence $\Lambda $ is not silting-discrete by Corollary 2.11.
Remark 3.10. As an analog of silting-discreteness, the notion of the tilting-discreteness for (self-injective) algebras was introduced by Chan, Koenig, and Liu. It is known that any representation-finite self-injective algebra (so, every self-injective Nakayama algebra) is tilting-discrete [Reference Aihara and Mizuno10], [Reference Chan, Koenig and Liu22].
Appendix A. Derived-discrete algebras are silting-discrete
The aim of this appendix is to give an approach to checking the silting-discreteness by classification of indecomposable objects. As a corollary, we obtain that any derived-discrete algebra is silting-discrete [Reference Yao and Yang56, Exam. 3.9 and Cor. 4.2]; the case that it has finite global dimension is due to [Reference Broomhead, Pauksztello and Ploog21]. Here is the main theorem of this appendix.
Theorem A.1. Assume that for each integer $d>0$ , there exists an upper bound of the dimensions of $\operatorname {Hom}_\Lambda (\oplus _{i\in \mathbb {Z}}P^i, \Lambda /\operatorname {rad} \Lambda )$ for all indecomposable perfect complexes P with length d. Then $\Lambda $ is silting-discrete.
Proof. By [Reference Huisgen-Zimmermann and Saorin30, Cor. 9] (see also [Reference Al-Nofayee and Rickard11, Th. 1.1]), the assumption implies that there are only finitely many indecomposable presilting complexes of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ with length d, which derives that $\mathsf {d}_{\Lambda }\operatorname{-silt}\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ is finite. Thus, $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ is silting-discrete.
For example, the assumption of Theorem A.1 is satisfied if $\Lambda $ is a derived-discrete algebra [Reference Bekkert and Merklen19], [Reference Bobinski, Geiss and Skowronski20] (see also [Reference Arnesen, Laking, Pauksztello and Prest13]). So, we recover the result of Yao–Yang.
Corollary A.2. Any derived-discrete algebra is silting-discrete. In particular, every Nakayama algebra with radical square zero is silting-discrete.
Proof. Let $\Lambda $ be a derived-discrete algebra, but not piecewise hereditary of Dynkin type. By [Reference Bobinski, Geiss and Skowronski20], we see that $\Lambda $ is derived equivalent to the algebra presented by the quiver with relations for some $1\leq r\leq n$ and $m\geq 0$ :
It follows from [Reference Bekkert and Merklen19] that each term of an indecomposable perfect complex is a multiplicity-free projective module, which means that $\Lambda $ satisfies the assumption of Theorem A.1, so it is silting-discrete.
Appendix B. Triangulated categories whose silting objects are tilting
The gap between siltings and tiltings has been often drawing attention lately (see, e.g., [Reference Adachi and Kase3], [Reference August and Dugas17]). In this appendix, we explore when a triangulated category has only tilting objects; the main result of this appendix was used by the first-named author of this paper in the article [Reference Aihara6], but he gave no proof because it is easy. The aim of this appendix is to present a proof and examples of the main result.
We say that $\mathcal {T}$ is asotic if any silting object in $\mathcal {T}$ is tilting; the word asotic is an abbreviation of the phrase “Any Silting Object is Tilting” $+$ the suffix “-ic.”
In this appendix, algebras are always finite-dimensional K-algebras which are basic and ring-indecomposable, unless otherwise noted.
The first example of asotic triangulated categories is a triangulated category with an indecomposable tilting object [Reference Aihara and Iyama9, Th. 2.26]; such a triangulated category can be written as the perfect derived category of a local algebra. In the following, let us consider the nonlocal case.
We say that $\mathcal {T}$ is $\ell $ -Calabi–Yau if there is a bifunctorial isomorphism $\operatorname {Hom}_{\mathcal {T}}(-,?)\simeq D\operatorname {Hom}_{\mathcal {T}}(?,-[\ell ])$ , where D stands for the K-dual. Here is an easy example of asotic triangulated categories (see [Reference Aihara and Iyama9, Lem. 2.7 and Exam. 2.8]).
Example B.1. A 0-Calabi–Yau triangulated category is asotic. In particular, the perfect derived category of a symmetric algebra is 0-Calabi–Yau, and so it is asotic.
We also know that a (complete) preprojective algebra of extended Dynkin type admits an asotic perfect derived category [Reference Kimura and Mizuno37, Prop. A.1]; note that the algebra is not finite-dimensional and the perfect derived category has symmetry like 0-Calabi–Yau property.
The main result of this appendix gives a slight generalization of Example B.1. Leaving the details for silting mutation to the paper [Reference Aihara and Iyama9], we use the terminologies $\mu _X^-(T)$ and $\mu _X^+(T)$ for the left and right mutations of a silting object T at its direct summand X.
Theorem B.2. Let $\Lambda $ be an algebra and $\mathcal {T}:=\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ .
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(1) The following are equivalent:
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(i) $\mu _P^-(\Lambda )$ is tilting for any indecomposable projective module P.
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(ii) The top of the indecomposable injective module corresponding to S is the direct sum of some copies of S for every simple module S.
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(2) The following are equivalent:
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(i) $\mu _P^+(\Lambda )$ is tilting for any indecomposable projective module P.
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(ii) The socle of the indecomposable projective module corresponding to S is the direct sum of some copies of S for every simple module S.
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Proof. We show (2); the other can be handled dually. Let S be a simple module and P its corresponding indecomposable projective module which is of the form $e\Lambda $ for a primitive idempotent e of $\Lambda $ . Then, we observe that the right mutation $\mu _P^+(\Lambda )$ is the direct sum of a complex X and the stalk complex $\Lambda /P$ concerned in degree 0, where X is the $(-1)$ -shift of the projective presentation of $M:=e\Lambda /e\Lambda (1-e)\Lambda $ . Note that the second syzygy $\Omega ^2(M)$ of M is contained in the direct sum of some copies of $\Lambda /P$ [Reference Aihara and Iyama9, Lem. 2.25]. Thus, the equivalence (i) $\Leftrightarrow $ (ii) can be checked easily by an isomorphism $\operatorname {Hom}_{\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )}(\mu _P^+(\Lambda ), \mu _P^+(\Lambda )[-1])\simeq \operatorname {Hom}_\Lambda (M, \Lambda /P\oplus \Omega ^2(M))$ .
For example, weakly symmetric algebras satisfy the condition (ii) as in Theorem B.2(1)(2). Moreover, the weakly symmetric property of algebras is a derived invariant (see, e.g., [Reference August and Dugas17, Prop. 3.1]). These yield the following corollary.
Corollary B.3. Let $\Lambda $ be a weakly symmetric algebra and $\mathcal {T}:=\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . Let $\mathcal {C}$ be a connected component of the Hasse quiver of $\operatorname {\mathsf {silt}}\mathcal {T}$ . Then the following hold:
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(1) If $\mathcal {C}$ has a tilting object, then all members in $\mathcal {C}$ are tilting.
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(2) If $\Lambda $ is silting-connected, that is, $\mathcal {C}=\operatorname {\mathsf {silt}}\mathcal {T}$ , then $\mathcal {T}$ is asotic.
We give an example of nonsymmetric algebras whose perfect derived categories are asotic (see [Reference Adachi and Kase3], [Reference Aihara6], [Reference Aihara and Mizuno10], [Reference August and Dugas17]).
Example B.4. Let $\Lambda $ be the preprojective algebra of Dynkin type $D_{2n}, E_7$ or $E_8$ , which is nonsymmetric weakly symmetric. Then $\mathcal {T}:=\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ is asotic.
Proof. The strategy is due to [Reference Aihara and Mizuno10]; we give a proof here for the convenience of the reader.
By Theorem B.2, any (irreducible) silting mutation of $\Lambda $ is a tilting object whose endomorphism algebra is isomorphic to $\Lambda $ . So, for every sequence $\Lambda =:T_0, T_1, \ldots ,T_d$ of silting objects such that $T_{i+1}$ is the (left) silting mutation of $T_i$ at an indecomposable direct summand, we see that all $T_i$ ’s are tilting. Since the set $\mathsf {2}_{T_i}\operatorname {-silt}\mathcal {T}$ is finite, we obtain that $\mathcal {T}$ is silting-discrete; in particular, it is silting-connected. Thus, it turns out that $\mathcal {T}$ is asotic by Corollary B.3.
We remark that there are weakly symmetric algebras whose perfect derived categories are not asotic [Reference August and Dugas17, §4]. This says that for such an algebra $\Lambda $ , the Hasse quiver of $\operatorname {\mathsf {silt}}(\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda ))$ has a connected component consisting of nontilting silting objects. On the other hand, we know from [Reference August and Dugas17, Prop. 3.6] that for a weakly symmetric algebra $\Lambda $ , every silting object lying in $\mathsf {2}_{\Lambda }\operatorname {-silt}(\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda ))$ is tilting.
We also find nonweakly symmetric algebras with asotic perfect derived categories.
Proposition B.5. Let R be a local algebra, and let $\Lambda $ be a silting-discrete algebra. If $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ is asotic, then so is $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda \otimes _KR)$ .
Proof. The assertion follows from [Reference Aihara and Honma7, Th. 2.1].
B.1 Thick subcategories
As an application, we describe thick subcategories generated by silting objects (i.e., the thick closures of presilting objects) in terms of algebras associated with a given algebra; however, we will assume the Bongartz-type condition (i.e., every presilting object is partial silting). Since any silting-discrete triangulated category satisfies the Bongartz-type condition [Reference Aihara and Mizuno10, Th. 2.15], we can, for example, choose a silting-discrete symmetric algebra as our algebra.
The following proposition is practical to write out full triangulated subcategories with silting objects (up to triangle equivalence).
Proposition B.6. Let $\Lambda $ be an algebra whose perfect derived category is asotic and satisfies the Bongartz-type condition. Then every full triangulated subcategory of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ with a silting object can be realized as $\mathsf {K^b}(\operatorname {\mathsf {proj}} e\Gamma e)$ , up to triangle equivalence. Here, $\Gamma $ is an algebra derived equivalent to $\Lambda $ and e is its idempotent.
Proof. Let $\mathcal {U}$ be a full triangulated subcategory of $\mathcal {T}:=\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ with U silting. Since U is presilting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ , the Bongartz-type condition of $\mathcal {T}$ implies that U can be completed to a silting object $T:=U\oplus X$ of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . As $\mathcal {T}$ is asotic, it is seen that T is tilting in $\mathcal {T}$ , so U is tilting in $\mathcal {U}$ . Hence, $\Gamma :=\operatorname {End}_{\mathcal {T}}(T)$ is derived equivalent to $\Lambda $ . Take the composition e of the canonical morphisms $T\to U\to T$ , which is an idempotent of $\Gamma $ with $e\Gamma e\simeq \operatorname {End}_{\mathcal {T}}(U)$ . Since U is tilting in $\mathcal {U}$ , it turns out that there are triangle equivalences $\mathcal {U}\simeq \mathsf {K^b}(\operatorname {\mathsf {proj}}\operatorname {End}_{\mathcal {T}}(U))\simeq \mathsf {K^b}(\operatorname {\mathsf {proj}} e\Gamma e)$ .
Let us give an easy example.
Example B.7. Let $\Lambda :=\Lambda _0$ be the multiplicity-free Brauer star algebra with three edges; that is, its Brauer tree is:
As is well-known [Reference Rickard49], there are two derived equivalent algebras to $\Lambda $ ; one is $\Lambda $ itself and the other is the multiplicity-free Brauer line algebra $\Lambda _1$ with three edges. Taking idempotent truncations, we get three kinds of Brauer tree algebras other than $\Lambda $ and $\Lambda _1$ ; the Brauer tree algebras $\Lambda _2, \Lambda _3$ , and $\Lambda _4$ whose Brauer trees are $G_2$ , $G_3$ , and $G_3\times G_3$ , respectively:
By Proposition B.6, these give all (nonzero) full triangulated subcategories of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ with siltings, which are triangle equivalent to $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda _i)$ for $i\in \{0,1,2,3,4\}$ .
Even if a given full triangulated subcategory has a tilting object, it does not necessarily possess partial tilting in the whole; the following example first appeared in [Reference Rickard and Schofield50].
Example B.8. Let $\Lambda $ be the algebra presented by the quiver
with relations $\alpha \beta =\gamma \delta =\delta \alpha =0$ . Then, $\Lambda $ has global dimension 4, and the simple module S corresponding to the vertex 1 is a partial tilting module with projective dimension 2; hence, it is pretilting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . Let $\mathcal {U}$ be the thick closure of S in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . Then, $\mathcal {U}$ has a tilting object S, but its (pre)tilting objects are never partial tilting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ .
Indeed, the Grothendieck group of $\mathcal {U}$ has rank 1, so $\operatorname {\mathsf {silt}}\mathcal {U}=S[\mathbb {Z}]$ . However, we obtain from [Reference Liu, Vitoria and Yang40, Exam. 4.4] that for any $n\in \mathbb {Z}$ , $S[n]$ is not partial tilting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . Thus, $\mathcal {U}$ has no partial tilting object of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ . On the other hand, S is partial silting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ ; actually, $S\oplus \Lambda /P[2]$ is silting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Lambda )$ , where P stands for the indecomposable projective module corresponding to the vertex 1.
Remark B.9. A crux of Proposition B.6 is that our triangulated category satisfies the Bongartz-type condition but not asotic; that is, the classification of thick subcategories with siltings can be done by using idempotent truncations of dg algebras. However, we here avoided doing that because it is very difficult to classify all derived equivalent dg algebras to the original. In this case, the asoticness condition was useful.
B.2 Remark on Bongartz-type condition
Recently, it was pointed out in [Reference Liu and Zhou42] that the Bongartz-type condition for presiltings does not necessarily hold. Let us recall it here.
We consider the algebra $\Gamma $ presented by the quiver . Let $S:=P_2/(y)$ ; it has projective dimension 2 and is pretilting in $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Gamma )$ . Here, $P_i$ stands for the indecomposable projective module corresponding to the vertex i. Now, we find a thick generator $S\oplus P_2\oplus P_3$ of $\mathsf {K^b}(\operatorname {\mathsf {proj}}\Gamma )$ whose dg endomorphism algebra $\Lambda $ is given by the quiver as in Example B.8 with $\deg (\delta )=2$ ; by the Keller–Rickard theorem, there is a derived equivalence between $\Gamma $ and $\Lambda $ which sends $S_\Gamma $ to ${P_1}_\Lambda $ . Applying the silting reduction (Theorem 2.15 and Corollary 2.17) to $\Lambda $ , we get isomorphisms $\operatorname {\mathsf {silt}}_S\Gamma \simeq \operatorname {\mathsf {silt}}_{P_1}\Lambda \simeq \operatorname {\mathsf {silt}}\mathcal {A}$ of posets. Here, $\mathcal {A}$ is the dg quiver algebra given by with $\gamma \varepsilon =0=\varepsilon \beta $ and $\deg (\varepsilon )=1$ (trivial differential). It was proved that $\operatorname {\mathsf {silt}}_S\Gamma =\emptyset $ in [Reference Liu and Zhou42] and $\operatorname {\mathsf {silt}}\mathcal {A}=\emptyset $ in [Reference Chang, Jin and Schroll23]; that is, S is not partial silting.
Remark B.10. As seen above, silting reduction sometimes makes a triangulated category without silting. We give a list of triangulated categories without silting:
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• the singularity category $\mathsf {D_{sg}}(\Lambda )$ for a finite-dimensional algebra $\Lambda $ ; in particular, the stable module category $\operatorname {\underline {\mathsf {mod}}}\Lambda $ for a self-injective algebra $\Lambda $ [Reference Aihara, Honma, Miyamoto and Wang8], [Reference Aihara and Iyama9], [Reference Chen, Li, Zhang and Zhao24];
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• a positively Calabi–Yau triangulated category [Reference Aihara and Iyama9];
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• the perfect derived category $\operatorname {\mathsf {per}}(\mathcal {A})$ for $\mathcal {A}$ as above with the same relations but with $\deg (\beta )+\deg (\varepsilon )=1=\deg (\gamma )+\deg (\varepsilon )$ [Reference Chang, Jin and Schroll23], [Reference Jin, Schroll and Wang32].
Acknowledgements
The authors would like to give their gratitude to Osamu Iyama and Norihiro Hanihara for useful discussions and giving a lot of valuable and helpful comments. They are also grateful to the referees for a careful reading of this paper and for many thoughtful comments and suggestions.