Tight bound for powers of Hamilton cycles in tournaments

TL;DR

This paper determines the precise degree conditions needed in large tournaments to guarantee the presence of the k-th power of a Hamilton cycle, refining previous bounds and establishing near-optimal error terms.

Contribution

It provides a sharp bound on degree conditions for powers of Hamilton cycles in tournaments, improving prior results and clarifying the minimal degree thresholds.

Findings

Established that degree at least n/4 + c n^{1-1/ceil(k/2)} guarantees the k-th power of a Hamilton cycle.

Constructed examples showing the lower bound on the error term is tight up to a constant, assuming a conjecture on Turán numbers.

Proved the theorem holds for n = ε^{- heta(k)}, which is optimal.

Abstract

A basic result in graph theory says that any $n$-vertex tournament with in- and out-degrees larger than $\frac{n-2}{4}$ contains a Hamilton cycle, and this is tight. In 1990, Bollob\'{a}s and H\"{a}ggkvist significantly extended this by showing that for any fixed $k$ and $\varepsilon > 0$, and sufficiently large $n$, all tournaments with degrees at least $\frac{n}{4}+\varepsilon n$ contain the $k$-th power of a Hamilton cycle. Up until now, there has not been any progress on determining a more accurate error term in the degree condition, neither in understanding how large $n$ should be in the Bollob\'{a}s-H\"{a}ggkvist theorem. We essentially resolve both of these questions. First, we show that if the degrees are at least $\frac{n}{4} + cn^{1-1/\lceil k/2 \rceil}$ for some constant $c = c(k)$, then the tournament contains the $k$-th power of a Hamilton cycle. In particular, in order to guarantee the square of a Hamilton cycle, one only requires a constant additive term. We also present a construction which, modulo a well-known conjecture on Tur\'an numbers for complete bipartite graphs, shows that the error term must be of order at least $n^{1-1/\lceil (k-1)/2 \rceil}$, which matches our upper bound for all even $k$. For odd $k$, we believe that the lower bound can be improved. Indeed, we show that for $k=3$, there exist tournaments with degrees $\frac{n}{4}+\Omega(n^{1/5})$ and no cube of a Hamilton cycle. In addition, our results imply that the Bollob\'{a}s-H\"{a}ggkvist theorem already holds for $n = \varepsilon^{-\Theta(k)}$, which is best possible.