On graphs with no induced bull and no induced diamond

A bull is the graph obtained by adding two pendant edges at different vertices of a triangle. A diamond is the graph obtained from a $K_4$ by deleting an edge. In this paper, we study the upper bound for the chromatic number of (bull, diamond)-free graphs. Let $H$ be a graph such that every ($H$, triangle)-free graph is $k$-colorable, for some natural number $k$. We show that every ($H$, bull, diamond)-free graph $G$ has chromatic number at most $\max\{2k,\omega(G)\}$, where $\omega(G)$ denotes the clique number of $G$. Let $G$ be a triangle-free graph with $n$ vertices and $m$ edges. Poljak and Tuza [SIAM J. Discrete Math., 7 (1994), pp. 307--313] showed that the chromatic number of $G$ is at most $\min\{4\sqrt{n/\log n}, \frac{14m^{1/3}}{(\log m)^{2/3}}\}$. Harris [SIAM J. Discrete Math., 33 (2019), pp. 546--566] showed that the chromatic number of $G$ is at most $2\sqrt{n}+(6t)^{1/3}$, where $t$ is the number of triangle in $G$. Here we show, a (bull, diamond)-free graph $H$ with $n$ vertices and $m$ edges, is either $\omega(H)$-colorable, or the chromatic number of $H$ is at most $\min\{4\sqrt{n},8\sqrt{n/\log n}, \frac{28m^{1/3}}{(\log m)^{2/3}}\}$.