Proof. Suppose $\Lambda =kQ/I$ , and let $X \in \operatorname{\mathrm{ind}}(\Lambda )$ be projective-injective. Then, $X=P_x=I_z$ , for a pair of vertices x and z in $Q_0$ . Hence, $X= \Lambda e_x$ and $\operatorname{\mathrm{soc}}(X)$ is a subspace of $e_z \Lambda e_x$ . Note that $\operatorname{\mathrm{soc}}(X)$ is simple and $\Lambda $ is basic. Then, we have $\dim _k(\operatorname{\mathrm{soc}}(X))=1$ . Consider the ideal $J:=\langle \rho \rangle $ , where $\rho $ denotes the element of $e_z \Lambda e_x \subseteq kQ/I$ associated with $\operatorname{\mathrm{soc}}(X)$ . Then J is one-dimensional and $JY=0$ if and only if $Y\not \simeq X$ . Consequently, $\operatorname{\mathrm{brick}}(\Lambda ) \setminus \{X\} \subseteq \operatorname{\mathrm{brick}} (\Lambda /J) \subseteq \operatorname{\mathrm{brick}}(\Lambda )$ . Then, the first part of the assertion follows from Theorem 2.1. Moreover, the second part is an immediate consequence of the minimality assumption.

Proof. Suppose $\Lambda $ is $\tau $ -tilting infinite. Without loss of generality, we can assume $\Lambda $ is min- $\tau $ -infinite. By Proposition 3.2, $\Lambda $ is node-free. Therefore, $\operatorname{\mathrm{rad}}^2(\Lambda )=0$ implies that $\Lambda =kQ$ , for a sink-source quiver Q. To finish the proof, we use the fact that hereditary algebras of affine type are $\tau $ -tilting infinite and obviously minimal with respect to this property.

Proof. As a consequence of [Reference Eisele, Janssens and RaedscheldersEJR, Th. 1] and [Reference Demonet, Iyama and JassoDIJ], for any algebra $\Lambda $ and each ideal J generated by some elements in $Z(\Lambda )\cap \operatorname{\mathrm{rad}}(\Lambda )$ , the sets $\tau \operatorname{\mathrm{rigid}}(\Lambda )\cap \operatorname{\mathrm{ind}}(\Lambda )$ and $\tau \operatorname{\mathrm{rigid}} (\Lambda /J)\cap \operatorname{\mathrm{ind}}(\Lambda /I)$ are in bijection. In particular, $\Lambda $ is $\tau $ -tilting finite if and only if $\Lambda /J$ is so.

Now, assume $\Lambda =kQ/I$ is min- $\tau $ -infinite. Obviously, $|Q_0|=n \geq 2$ (otherwise, $\Lambda $ is local and therefore $\tau $ -tilting finite). Moreover, by the minimality assumption, we have $Z(\Lambda ) \cap \operatorname{\mathrm{rad}}(\Lambda )=0$ .

Every element of $\Lambda =kQ/I$ can be expressed as $\rho :=\sum _{i=1}^{n} \lambda _i e_i+ r+I$ , where $\lambda _i \in k$ , and r is a linear combination of paths of positive length in Q. Suppose $\alpha $ is an arrow in Q with $s(\alpha )=i$ and $e(\alpha )=j$ . Then, multiplying $\rho $ by $\alpha $ from the left and from the right, and then reducing modulo $\operatorname{\mathrm{rad}}^2 (\Lambda )$ , we get $\lambda _i \alpha =\lambda _j \alpha $ . Since Q is a connected quiver, we have all $\lambda _i$ are equal. Consequently, we have $\rho = \lambda \cdot 1 + r + I$ , for some $\lambda \in k$ . Since $\lambda \cdot 1 + I \in Z(\Lambda )$ , we get that $r + I \in Z(\Lambda )$ . Moreover, from $Z(A) \cap \operatorname{\mathrm{rad}}(\Lambda )= 0$ , it follows that $r \in I$ . Therefore, $\rho = \lambda \cdot 1$ .

Proof. To show $(1)$ , suppose $\Lambda $ is min-rep-inf. If there exists $M \in \operatorname{\mathrm{Ind}}(\Lambda )\setminus \operatorname{\mathrm{ind}}(\Lambda )$ with $\operatorname{\mathrm{ann}}_{\Lambda }(M)\neq 0$ , then for the quotient algebra $\Lambda ':=\Lambda /\langle \operatorname{\mathrm{ann}}_{\Lambda }(M) \rangle $ , we have $M \in \operatorname{\mathrm{Ind}}(\Lambda ')\setminus \operatorname{\mathrm{ind}}(\Lambda ')$ . Since $\Lambda '$ is rep-finite, the desired contradiction follows from Theorem 3.6.

For the converse, let us assume that $\Lambda $ is not min-rep-infinite. Thus, for some nonzero ideal $J \in \Lambda $ , the quotient algebra $\Lambda /J$ is rep-infinite and, again by Theorem 3.6, there exists M in $\operatorname{\mathrm{Ind}}(\Lambda /J)\setminus \operatorname{\mathrm{ind}}(\Lambda /J)$ . However, M also belongs to $\operatorname{\mathrm{Ind}}(\Lambda )\setminus \operatorname{\mathrm{ind}}(\Lambda )$ and it is not faithful. So, we get the desired contradiction.

In the above proof, if we replace the indecomposable modules by bricks, we obtain a proof of $(2)$ .

Proof. Suppose $\{T_i\}_{i\in \mathbb {N}}$ is a family of pairwise non-isomorphic unfaithful modules in $\operatorname {\tau -rigid}(\Lambda )$ , and let $\mathcal {T}_i = \mathrm {Fac}(T_i)$ be the corresponding functorially finite torsion classes. From the beginning, we can assume every $T_i$ is a nonzero support $\tau $ -tilting module.

We want to construct an infinite strictly ascending chain of functorially finite torsion classes as follows. Set $\mathcal {U}_0 : = \{0\}$ , which is clearly functorially finite and is contained in all $\mathcal {T}_i$ . It follows from [Reference Demonet, Iyama and JassoDIJ, Th. 1.3] that for each j, there is a right mutation $\mathcal {U}_{1}^j$ of $\mathcal {U}_0$ with $\mathcal {U}_0 \subsetneq \mathcal {U}_{1}^j \subseteq \mathcal {T}_j$ . Since the Hasse quiver of the poset of functorially finite torsion classes of $\mathrm {mod}\Lambda $ is n-regular, there is a (functorially finite) right mutation $\mathcal {U}_1$ of $\mathcal {U}_0$ such that $\mathcal {U}_1^j = \mathcal {U}_1$ for infinitely many $j \in \mathbb {N}$ . Note that for all but at most one such j, the inclusion $\mathcal {U}_1 \subseteq \mathcal {T}_j$ is proper. By induction, assume that we have constructed a functorially finite torsion class $\mathcal {U}_i$ that is properly contained in infinitely many $\mathcal {T}_j$ . For any such j, we again apply [Reference Demonet, Iyama and JassoDIJ, Th. 1.3] to get a right mutation $\mathcal {U}_{i+1}^j$ of $\mathcal {U}_i$ with $\mathcal {U}_i \subsetneq \mathcal {U}_{i+1}^j \subseteq \mathcal {T}_j$ . As before, we construct $\mathcal {U}_{i+1}$ as a functorially finite torsion class that coincides with infinitely many of the $\mathcal {U}_{i+1}^j$ . Once again, observe that $\mathcal {U}_{i+1}^j \subseteq \mathcal {T}_j$ is proper for infinitely many j. This yields a chain

$$ \begin{align*}0=\mathcal{U}_0 \subset \mathcal{U}_1 \subset \mathcal{U}_2 \subset \cdots\end{align*} $$

of functorially finite torsion classes such that each $\mathcal {U}_i$ is contained in infinitely many $\mathcal {T}_j$ . Because each $\mathcal {T}_j$ is unfaithful, so is every $\mathcal {U}_i$ . If $J_i$ denotes the annihilator of $\mathcal {U}_i$ , we get a corresponding descending chain

$$ \begin{align*}\cdots \subseteq J_2 \subseteq J_1 \subseteq J_0\end{align*} $$

of nonzero ideals. Since ideals of $\Lambda $ are finite-dimensional, this chain has to stabilize to a nonzero ideal I, implying that there is a positive integer r such that $I = J_{r+j}$ for all $j \ge 0$ . For all $i \in \mathbb {N}$ , observe that each $\mathcal {U}_i$ , and therefore the algebra $\Lambda /J_i$ , has at least i non-isomorphic bricks. Indeed, for each i, there is at least one brick that belongs to $\mathcal {U}_i$ but not to $\mathcal {U}_{i-1}$ . Thus, $\Lambda /I$ has infinitely many non-isomorphic bricks, and by Theorem 2.1, $\Lambda /I$ is $\tau $ -tilting infinite. This contradicts the minimality assumption on $\Lambda $ . Thus, almost every $\tau $ -rigid $\Lambda $ -module is faithful.

The last assertion follows from the fact that, for any algebra, any faithful $\tau $ -rigid module is partial tilting.

Proof. This follows from the inclusions $\operatorname{\mathrm{tilt}}(\Lambda ) \subseteq \tau \operatorname{-\textrm{tilt}}(\Lambda ) \subseteq s\tau \operatorname{-\textrm{tilt}}(\Lambda )$ , and the fact that $\tau \operatorname{-\textrm{tilt}}(\Lambda )$ consists of sincere modules in $s\tau \operatorname{-\textrm{tilt}}(\Lambda )$ . By Theorem 4.2, almost all support $\tau $ -tilting $\Lambda $ -modules are faithful as $\Lambda $ -modules, and thus almost all $\tau $ -tilting modules are tilting. It is evident that if $\Lambda $ is a min- $\tau $ -inf algebra, then it must be minimal tilting infinite. If the converse fails, there exists a proper quotient $\Lambda /J$ which is min- $\tau $ -infinite. Now, the desired contradiction immediately follows from the first part.

Proof. Let B be a faithful brick of dimension d in $\operatorname{\mathrm{mod}} \Lambda /I_1$ . For each $i \ge 2$ , let $B_i$ be the brick of $\Lambda /I_i$ induced from the isomorphism $\varphi _i: \Lambda /I_i \to \Lambda /I_1$ . Then $B_i$ is faithful of dimension d. The $B_i$ are non-isomorphic as $\Lambda $ -modules since they have pairwise distinct annihilators.

Proof. Let T be a $2$ -term silting complex in $K^b(\mathrm {proj}\Lambda )$ represented by $P_1 \to P_0$ . We assume that the differential is a radical morphism, and hence $P_0$ and $P_1$ are uniquely determined up to isomorphism. Let $\dim T$ denote the total dimension of T, given by $\dim _k P_0+ \dim _k P_1$ .

Using the same notation as in the paragraph preceding the lemma, we assume $T'$ is the right mutation of T at X. Let $\dim \mathrm {Hom}(U,X)=m$ . Then we have a right $\mathrm {add}(U)$ -approximation $U^m \to X$ of X. It is well known that there is a direct summand of $U^m$ , isomorphic to $U'$ , such that the corresponding restriction map is minimal. This yields $\dim U' \le m \, \dim U$ . Observe that an upper bound for $\dim \mathrm {Hom}(U,X)=m$ is given by $\dim \mathrm { Hom}(T,T)$ , which in turn is bounded above by $\dim \mathrm {Hom}(P_1,P_1)$ + $\dim \mathrm {Hom}(P_0,P_0)$ . Now, the latter is bounded above by $(\dim P_0)^2 + (\dim P_1)^2$ , which in turn does not exceed $2(\dim T)^2$ . Therefore,

$$ \begin{align*} \dim Y & \le \dim U' + \dim X \\ & \le m \, \dim U + \dim X \\ & \le (m+1) \dim T \\ & \le (2(\dim T)^2 + 1) \dim T, \end{align*} $$

and hence, as $\dim U \le \dim T$ , we get

$$ \begin{align*}\dim T' = \dim Y + \dim U \le (2(\dim T)^2 + 2)\dim T.\end{align*} $$

Note that for the minimal element of $s\tau \operatorname{-\textrm{tilt}}(\Lambda )$ , the corresponding element in the poset of $2$ -term silting complexes is $\Lambda \to 0$ , which has total dimension $d:=\mathrm {dim}_k\Lambda $ . Let T be a $2$ -term silting complex such that the interval $[0,T]$ in the Hasse quiver of poset of $2$ -term silting complexes has a path of length at most t. Then there is a function $g(d,t)$ which depends only on d and t such that $\mathrm {dim}T \le g(d,t)$ . Note that this function $g(d,t)$ is polynomial of degree $3^t$ in d.

Now, let T be at level at most t and $T'$ be a right mutation of T. By [Reference Assem, Simson and SkowrońskiAIR, Th. 3.2], the support $\tau $ -tilting module M (resp. $M'$ ) corresponding to T (resp. to $T'$ ) is the zeroth cohomology of T (resp. of T). Thus, $\dim M \leq \dim T \le g(d,t)$ and $\dim M' \leq \dim T' \le g(d,t+1)$ . By [Reference Assem, Simson and SkowrońskiAIR, Ths. 2.7 and 3.2], we assume that $\mathcal {T}$ denotes the functorially finite torsion class associated with T. Moreover, [Reference Assem, Simson and SkowrońskiAIR, Cors. 2.34 and 3.9] imply that $\mathcal {T}$ is at level at most t in the poset of functorially finite torsion classes of $\operatorname{\mathrm{mod}} \Lambda $ , with the covering relation $\mathcal {T} < \operatorname {Fac}(M')$ . Since the minimal extending brick B for the covering relation $\mathcal {T} < \operatorname {Fac}(M')$ is a quotient of $M'$ , we obviously have $\dim B \leq g(d,t+1)$ . This gives a function that bounds the dimension of all minimal extending brick for $\mathcal {T}$ .

Proof. Without loss of generality, assume that the family $\{I_i\}_{i\in A}$ is such that all ideals are of the same dimension, and this dimension is maximal with the property that each $\Lambda /I_i$ admits a faithful brick. If infinitely many of these $\Lambda /I_i$ are isomorphic, apply Lemma 5.1 and we are done. Thus, assume that $\Lambda /I_i$ are pairwise non-isomorphic. If $V_i$ denotes a faithful brick over $\Lambda /I_i$ , then $\{V_i\}_{i\in A}$ is a family of pairwise non-isomorphic modules in $\operatorname{\mathrm{brick}}(\Lambda )$ , particularly because $V_i$ have pairwise distinct annihilators in $\Lambda $ . If there is a bound on the dimension of bricks in $\{V_i\}_{i\in A}$ , we are done. Thus, for the sake of contradiction, we assume that there is no bound on the dimension of $\{V_i\}_{i\in A}$ .

For every functorially finite torsion class $\mathcal {T}$ at level s, by Lemma 5.2, there is a global bound on the dimension of all minimal extending bricks for $\mathcal {T}$ . We can start by picking a positive integer $d_1$ such that infinitely many of the $\Lambda /I_i$ have a brick in dimension $d_1$ (such as $d_1=1$ ). For each i, by $\mathcal {H}_i$ , we denote the Hasse quiver of the functorially finite torsion classes in $\operatorname{\mathrm{mod}} \Lambda /I_i$ . There is an arrow $\mathcal {T} \to \mathcal {T'}$ in $\mathcal {H}_i$ precisely when $\mathcal {T} < \mathcal {T}'$ is a covering relation. Since we assume that there is no bound on the dimension of $\{V_i\}_{i\in A}$ , that means from Lemma 5.2 that the $\mathcal {H}_i$ have arbitrarily large heights.

Claim: For a fixed dimension s, we may assume that there is a function $h(s)$ such that every path in any given $\mathcal {H}_i$ has at most $h(s)$ minimal extending bricks of dimension at most s. To prove the claim, assume otherwise. Hence, there is a dimension $s' \le s$ such that we can find paths in the $\mathcal {H}_i$ having arbitrarily large number of minimal extending bricks of dimension $s'$ . Note that in a given path, the minimal extending bricks are pairwise non-isomorphic. For the bricks of dimension $s'$ over all $\Lambda /I_i$ , if their annihilators in $\Lambda $ form an infinite family of pairwise distinct ideals, then we are done. Therefore, we are in the case where there is an ideal J such that $\Lambda /J$ has an infinite number of non-isomorphic bricks of dimension $s'$ , and similarly we are done. This proves our claim.

By the claim, the number of bricks of dimension at most $d_1$ on any given path of each $\mathcal {H}_i$ is bounded by $h(d_1)$ . Pick a positive integer $l_2> h(d_1)$ . We know that we have infinitely many $\mathcal {H}_i$ , each of which having at least one path of length $l_2$ . By the claim, for each such i, $\mathcal {H}_i$ admits at least one minimal extending brick of dimension bigger than $d_1$ . However, it follows from Lemma 5.2 that the length of a brick on a path of length $l_2$ is bounded by a function that depends only on $l_2$ and the dimension of $\Lambda /I_i$ . Therefore, by the pigeonhole principle, there is a positive integer $d_2> d_1$ such that infinitely many of the $\Lambda /I_i$ have a brick of dimension $d_2$ . In general, for $k \ge 2$ , we pick $l_k> h(d_{k-1})$ and we get that there are infinitely many $\mathcal {H}_i$ having a path of length $l_k$ . As argued previously, there is a positive integer $d_k> d_{k-1}$ such that infinitely many of the $\Lambda /I_i$ have a brick of dimension $d_k$ .

If for a given r, infinitely many of the bricks of dimension $d_r$ are faithful over the corresponding $\Lambda /I_i$ , then we are done, as we obtain an infinite family of non-isomorphic bricks over $\Lambda $ of the same dimension $d_r$ . Fix $r \ge 1$ . Assume without loss of generality that each $\Lambda /I_i$ has an unfaithful brick $B_i$ of dimension $d_r$ . Let $J_i:=\operatorname{\mathrm{ann}}_{\Lambda }(B_i)$ , then $I_i \subsetneq J_i$ . If the ideals $J_i$ form an infinite family, then again, we get that the $B_i$ form an infinite family of non-isomorphic bricks of dimension $d_r$ . We may thus assume that infinitely many of the $B_i$ have the same annihilator $J_{d_r}$ . In particular, the algebra $\Lambda /J_{d_r}$ has a faithful brick of dimension $d_r$ . We need only to consider the case where these $B_i$ are (almost all) isomorphic.

Thus, we are left with the situation such that for each $r \ge 1$ , we have an ideal $J_{d_r}$ with $\Lambda /J_{d_r}$ having a faithful brick of dimension $d_r$ . We may assume that infinitely many of the ideals in the family $\{J_{d_r}\}$ are pairwise distinct, as otherwise a proper quotient of $\Lambda $ admits infinitely many unbounded bricks, and this contradicts the fact that each $\Lambda /J_{d_r}$ is $\tau $ -tilting finite. Now, the family $\{J_{d_r}\}_{r \ge 1}$ yields an infinite family of ideals of the same dimension which are pairwise distinct and each $\Lambda /J_{d_r}$ admits a faithful brick. This gives the desired contradiction with our assumption at the beginning of the proof on the dimension of ideals in the family $\{I_i\}_{i \in A}$ .

Proof. Let $\mathrm {Fac}(N)$ be an arbitrary functorially finite torsion class, where N is assumed to be a basic support $\tau $ -tilting module corresponding to a $\tau $ -rigid pair $(N,P)$ where P is projective with $\operatorname {Hom}(P,N)=0$ and N is $\tau $ -tilting over its support. It follows from [Reference Demonet, Iyama, Reading, Reiten and ThomasDIR+, Prop. 4.13] that any minimal extending brick X labeling an arrow $\mathrm {Fac}(N) \to \mathcal {T}$ lies in $M^{\bot } \cap ^\perp \tau M \cap P^\perp $ where M is a direct summand of N. By [Reference JassoJ2, Th. 3.8], the category $M^{\bot } \cap ^\perp \tau M \cap P^\perp $ is equivalent to the module category $\operatorname{\mathrm{mod}} A$ , for a finite-dimensional local algebra A (see also [Reference Demonet, Iyama, Reading, Reiten and ThomasDIR+, Th. 4.12b]). Hence, X is the unique brick in $M^{\bot } \cap ^\perp \tau M \cap P^\perp $ . Let $\underline {\dim }(X)=\mathbf {d}$ and consider the representation variety $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ . Observe that the function $Y \mapsto \mathrm {dim}\operatorname {Hom}(M,Y)$ from $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ to $\mathbb {N}$ is upper-semicontinuous. Hence, the conditions $\operatorname {Hom}(M,-)=0$ defines an open set $U_1$ in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ . Similarly, the conditions $\operatorname {Hom}(-,\tau M)=0$ and $\operatorname {Hom}(P,-)=0$ also define respective open sets $U_2$ and $U_3$ in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ . Therefore, $U:=U_1 \cap U_2 \cap U_3$ is a nonempty open set which contains X. Furthermore, let $\operatorname{\mathrm{brick}}(\Lambda , \mathbf {d})$ denote the set of bricks in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ . Note that the orbit of a representation B in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ is of dimension $\mathrm {dim} \operatorname{\mathrm{GL}}(\mathbf {d}) - \mathrm { dim} \mathrm {End}(B)$ , and hence of maximal dimension when B is a brick. Hence, it follows that $\operatorname{\mathrm{brick}}(\Lambda , \mathbf {d})$ also forms an open set in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ , since the map that associates to a representation in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ the dimension of its orbit is upper-semi-continuous. Consequently, we have a nonempty open set $U\cap \operatorname{\mathrm{brick}}(\Lambda , \mathbf {d})$ in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ which consists of bricks. However, as mentioned above, X is the unique brick in $M^{\bot } \cap ^\perp \tau M \cap P^\perp $ , which implies that the orbit of X must be open in $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ .

Proof. We only show the necessity, as the sufficiency follows directly from Theorem 2.1. In the Hasse diagram of the functorially finite torsion classes of $\Lambda $ , consider an infinite path starting at the minimal element. The corresponding minimal extending bricks form an infinite family of pairwise non-isomorphic bricks. We know that, for each dimension vector $\mathbf {d}$ , the variety $\operatorname{\mathrm{rep}}(\Lambda , \mathbf {d})$ has only finitely many irreducible components, and the closure of each open orbit provides an irreducible component. Hence, Proposition 6.1 implies that for each $\mathbf {d}$ there are only finitely many minimal extending bricks whose dimension vector is $\mathbf {d}$ . Now, the desired result is immediate.