Highly connected subgraphs with large chromatic number
For integers $k\ge1$ and $m\ge2$, let $g(k,m)$ be the least integer $n\ge1$ such that every graph with chromatic number at least $n$ contains a $(k+1)$-connected subgraph with chromatic number at least $m$. Refining the recent result Gir\~ao and Narayanan that $g(k-1,k)\le 7k+1$ for all $k\ge2$, we...
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| creator | Nguyen, Tung H |
| description | For integers $k\ge1$ and $m\ge2$, let $g(k,m)$ be the least integer $n\ge1$
such that every graph with chromatic number at least $n$ contains a
$(k+1)$-connected subgraph with chromatic number at least $m$. Refining the
recent result Gir\~ao and Narayanan that $g(k-1,k)\le 7k+1$ for all $k\ge2$, we
prove that $g(k,m)\le \max(m+2k-2,\lceil(3+\frac{1}{16})k\rceil)$ for all
$k\ge1$ and $m\ge2$. This sharpens earlier results of Alon, Kleitman, Saks,
Seymour, and Thomassen, of Chudnovsky, Penev, Scott, and Trotignon, and of
Penev, Thomass\'{e}, and Trotignon.
Our result implies that $g(k,k+1)\le\lceil(3+\frac{1}{16})k\rceil$ for all
$k\ge1$, making a step closer towards a conjecture of Thomassen from 1983 that
$g(k,k+1)\le 3k+1$, which was originally a result with a false proof and was
the starting point of this research area. |
| doi_str_mv | 10.48550/arxiv.2206.00561 |
| format | Article |
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such that every graph with chromatic number at least $n$ contains a
$(k+1)$-connected subgraph with chromatic number at least $m$. Refining the
recent result Gir\~ao and Narayanan that $g(k-1,k)\le 7k+1$ for all $k\ge2$, we
prove that $g(k,m)\le \max(m+2k-2,\lceil(3+\frac{1}{16})k\rceil)$ for all
$k\ge1$ and $m\ge2$. This sharpens earlier results of Alon, Kleitman, Saks,
Seymour, and Thomassen, of Chudnovsky, Penev, Scott, and Trotignon, and of
Penev, Thomass\'{e}, and Trotignon.
Our result implies that $g(k,k+1)\le\lceil(3+\frac{1}{16})k\rceil$ for all
$k\ge1$, making a step closer towards a conjecture of Thomassen from 1983 that
$g(k,k+1)\le 3k+1$, which was originally a result with a false proof and was
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such that every graph with chromatic number at least $n$ contains a
$(k+1)$-connected subgraph with chromatic number at least $m$. Refining the
recent result Gir\~ao and Narayanan that $g(k-1,k)\le 7k+1$ for all $k\ge2$, we
prove that $g(k,m)\le \max(m+2k-2,\lceil(3+\frac{1}{16})k\rceil)$ for all
$k\ge1$ and $m\ge2$. This sharpens earlier results of Alon, Kleitman, Saks,
Seymour, and Thomassen, of Chudnovsky, Penev, Scott, and Trotignon, and of
Penev, Thomass\'{e}, and Trotignon.
Our result implies that $g(k,k+1)\le\lceil(3+\frac{1}{16})k\rceil$ for all
$k\ge1$, making a step closer towards a conjecture of Thomassen from 1983 that
$g(k,k+1)\le 3k+1$, which was originally a result with a false proof and was
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such that every graph with chromatic number at least $n$ contains a
$(k+1)$-connected subgraph with chromatic number at least $m$. Refining the
recent result Gir\~ao and Narayanan that $g(k-1,k)\le 7k+1$ for all $k\ge2$, we
prove that $g(k,m)\le \max(m+2k-2,\lceil(3+\frac{1}{16})k\rceil)$ for all
$k\ge1$ and $m\ge2$. This sharpens earlier results of Alon, Kleitman, Saks,
Seymour, and Thomassen, of Chudnovsky, Penev, Scott, and Trotignon, and of
Penev, Thomass\'{e}, and Trotignon.
Our result implies that $g(k,k+1)\le\lceil(3+\frac{1}{16})k\rceil$ for all
$k\ge1$, making a step closer towards a conjecture of Thomassen from 1983 that
$g(k,k+1)\le 3k+1$, which was originally a result with a false proof and was
the starting point of this research area.</abstract><doi>10.48550/arxiv.2206.00561</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Mathematics - Combinatorics |
| title | Highly connected subgraphs with large chromatic number |
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