The minimum number of clique-saturating edges
Let $G$ be a $K_p$-free graph. We say $e$ is a $K_p$-saturating edge of $G$ if $e\notin E(G)$ and $G+e$ contains a copy of $K_p$. Denote by $f_p(n, e)$ the minimum number of $K_p$-saturating edges that an $n$-vertex $K_p$-free graph with $e$ edges can have. Erd\H{o}s and Tuza conjectured that $f_4(n...
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Zusammenfassung: | Let $G$ be a $K_p$-free graph. We say $e$ is a $K_p$-saturating edge of $G$
if $e\notin E(G)$ and $G+e$ contains a copy of $K_p$. Denote by $f_p(n, e)$ the
minimum number of $K_p$-saturating edges that an $n$-vertex $K_p$-free graph
with $e$ edges can have. Erd\H{o}s and Tuza conjectured that $f_4(n,\lfloor
n^2/4\rfloor+1)=\left(1 + o(1)\right)\frac{n^2}{16}.$ Balogh and Liu disproved
this by showing $f_4(n,\lfloor n^2/4\rfloor+1)=(1+o(1))\frac{2n^2}{33}$. They
believed that a natural generalization of their construction for $K_p$-free
graph should also be optimal and made a conjecture that
$f_{p+1}(n,ex(n,K_p)+1)=\left(\frac{2(p-2)^2}{p(4p^2-11p+8)}+o(1)\right)n^2$
for all integers $p\ge 3$. The main result of this paper is to confirm the
above conjecture of Balogh and Liu. |
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DOI: | 10.48550/arxiv.2201.03983 |