$τ_d$-tilting theory for linear Nakayama algebras (2410.19505v2)

Abstract: Support $\tau$-tilting pairs, functorially finite torsion classes and $2$-term silting complexes are three much studied concepts in the representation theory of finite-dimensional algebras, which moreover turn out to be connected via work of Adachi, Iyama and Reiten. We investigate their higher-dimensional analogues via $\tau_d$-rigid pairs, $d$-torsion classes and $(d+1)$-term silting complexes as well as the connections between these three concepts. Our work is done in the setting of truncated linear Nakayama algebras $\Lambda(n,l)=\mathbf{k} \mathbb{A}{n}/\mathrm{rad}{\mathbf{k} \mathbb{A}{n}}^l$ admitting a $d$-cluster tilting module. More specifically, we classify $\tau_d$-rigid pairs $(M,P)$ of $\Lambda(n,l)$ with $|M|+|P|=n$ via an explicit combinatorial description and show that they can be characterized by a certain maximality condition as well as by giving rise to a $(d+1)$-term silting complex in $\mathrm{K}^b(\mathrm{proj}(\Lambda(n,l)))$. We also describe all $d$-torsion classes of $\Lambda(n,l)$. Finally, we compare our results to the classical case $d=1$ and investigate mutation with a special emphasis on the case where $d$ equals the global dimension of $\Lambda$.