Abstract
In 1983, Burr and Erdős initiated the study of Ramsey goodness problems. Nikiforov and Rousseau (2009) resolved almost all goodness questions raised by Burr and Erdős, in which the bounds on the parameters are of tower type since their proofs rely on the regularity lemma. Let Bk,n be the book graph on n vertices which consists of n−k copies of Kk+1 all sharing a common Kk, and let H=Kp(a1,…,ap) be the complete p-partite graph with parts of sizes a1,…,ap.Recently, avoiding use of the regularity lemma, Fox, He and Wigderson (2023) revisit several Ramsey goodness results involving books. They comment that it would be very interesting to see how far one can push these ideas. In particular, they conjecture that for all integers k,p,t≥2, there exists some δ>0 such that for all n≥1, 1≤a1≤⋯≤ap−1≤t and ap≤δn, we have r(H,Bk,n)=(p−1)(n−1)+dk(n,Ka1,a2)+1, where dk(n,Ka1,a2) is the maximum d for which there is an (n+d−1)-vertex Ka1,a2-free graph in which at most k−1 vertices have degree less than d. They verify the conjecture when a1=a2=1.We disprove the conjecture of Fox et al. (2023). Building upon the work of Fox et al., we make a substantial step by showing that for every k,p,t≥2, there exists δ>0 such that the following holds for all large n. Let 1≤a1≤…≤ap−1≤t and ap≤δn be positive integers. If a1=1, then r(H,Bk,n)≤(p−1)(n−1)+k(p−1)(a2−1)+1. The inequality is tight if a2|(n−1−k). Moreover, we prove that for every k,a≥1 and p≥2, there exists δ>0 such that for all large n and b≤δlnn, r(Kp(1,a,b,…,b),Bk,n)=(p−1)(n−1)+k(p−1)(a−1)+1 if a|(n−1−k), where the case when a=1 has been proved by Nikiforov and Rousseau (2009) using the regularity lemma. The bounds on 1/δ we obtain are not of tower-type since our proofs do not rely on the regularity lemma.
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Disclaimer: All third-party content on this website/platform is and will remain the property of their respective owners and is provided on "as is" basis without any warranties, express or implied. Use of third-party content does not indicate any affiliation, sponsorship with or endorsement by them. Any references to third-party content is to identify the corresponding services and shall be considered fair use under The CopyrightLaw.