Independence, induced subgraphs, and domination in K1,r-free graphs

Abstract

Let G be a graph and F a family of graphs. Define αF(G) as the maximum order of any induced subgraph of G that belongs to the family F. For the family F of graphs with chromatic number at most~k, we prove that if G is K1,r-free, then αF(G) (r-1)kγ(G), where γ(G) is the domination number. When F is the family of empty graphs, this bound simplifies to α(G) 2γ(G) for K1,3-free (claw-free) graphs, where α(G) is the independence number of G. For d-regular graphs, this is further refined to the bound α(G) 2(d+1d+2)γ(G), which is tight for d ∈ \2, 3, 4\. Using Ramsey theory, we extend this framework to edge-hereditary graph families, showing that for K1,r-free graphs, we have αF(G) r(Kr, F*)γ(G), where F* is the set of graphs not in F. Specializing to Kq-free graphs, we show αF(G) (r(Kq, Kr) - 1)γ(G). Finally, for the k-independence number αk(G), we prove that if G is K1,r-free with order n and minimum degree δ k+1, \[ αk(G) ( (r-1)(k+1)δ - k + (r-1)(k+1) ) n, \] and this bound is sharp for all parameters.