$\mathcal G$-systems
Abstract
A -system is a collection of -bases of with some extra axiomatic conditions. There are two kinds of actions "mutations" and "co-Bongartz completions" naturally acting on a -system, which provide the combinatorial structure of a -system. It turns out that "co-Bongartz completions" have good compatibility with "mutations". The constructions of "mutations" are known before in different contexts, including cluster tilting theory, silting theory, -tilting theory, cluster algebras, marked surfaces. We found that in addition to "mutations", there exists another kind of actions "co-Bongartz completions" naturally appearing in these different theories. With the help of "co-Bongartz completions" some good combinatorial results can be easily obtained. In this paper, we give the constructions of "co-Bongartz completions" in different theories. Then we show that -systems naturally arise from these theories, and the "mutations" and "co-Bongartz completions" in different theories are compatible with those in -systems.
Cite
@article{arxiv.1902.09218,
title = {$\mathcal G$-systems},
author = {Peigen Cao},
journal= {arXiv preprint arXiv:1902.09218},
year = {2020}
}
Comments
Comments are welcome. Twists in previous version are replaced by co-Bongartz completions. arXiv admin note: text overlap with arXiv:0809.2593 by other authors