A New Conjecture and Upper Bound on the Castelnuovo--Mumford Regularity of Binomial Edge Ideals (2405.14833v1)

Abstract: A famous theorem of Kalai and Meshulam is that $\mathrm{reg}(I + J) \leq \mathrm{reg}(I) + \mathrm{reg}(J) -1$ for any squarefree monomial ideals $I$ and $J$. This result was subsequently extended by Herzog to the case where $I$ and $J$ are any monomial ideals. In this paper we conjecture that the Castelnuovo--Mumford regularity is subadditive on binomial edge ideals. Specifically, we propose that $\mathrm{reg}(J_{G}) \leq \mathrm{reg}(J_{H_{1}}) + \mathrm{reg}(J_{H_{2}}) -1$ whenever $G$, $H_{1}$, and $H_{2}$ are graphs satisfying $E(G) = E(H_{1}) \cup E(H_{2})$ and $J_{\ast}$ is the associated binomial edge ideal. We prove a special case of this conjecture which strengthens the celebrated theorem of Malayeri--Madani--Kiani that $\mathrm{reg}(J_{G})$ is bounded above by the minimal number of maximal cliques covering the edges of the graph $G$. From this special case we obtain a new upper bound for $\mathrm{reg}(J_{G})$, namely that $\mathrm{reg}(J_{G}) \leq \mathrm{ht}(J_{G}) +1$. Our upper bound gives an analogue of the well-known result that $\mathrm{reg}(I(G)) \leq \mathrm{ht}(I(G)) +1$ where $I(G)$ is the edge ideal of the graph $G$. We additionally prove that this conjecture holds for graphs admitting a combinatorial description for its Castelnuovo--Mumford regularity, that is for closed graphs, bipartite graphs with $J_{G}$ Cohen--Macaulay, and block graphs. Finally, we give examples to show that our new upper bound is incomparable with Malayeri--Madani--Kiani's upper bound for $\mathrm{reg}(J_{G})$ given by the size of a maximal clique disjoint set of edges.