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New lower bounds on kissing numbers and spherical codes in high dimensions (2111.01255v3)

Published 1 Nov 2021 in math.CO

Abstract: Let the kissing number $K(d)$ be the maximum number of non-overlapping unit balls in $\mathbb Rd$ that can touch a given unit ball. Determining or estimating the number $K(d)$ has a long history, with the value of $K(3)$ being the subject of a famous discussion between Gregory and Newton in 1694. We prove that, as the dimension $d$ goes to infinity, $$ K(d)\ge (1+o(1)){\frac{\sqrt{3\pi}}{4\sqrt2}}\,\log\frac{3}{2}\cdot d{3/2}\cdot \Big(\frac{2}{\sqrt{3}}\Big){d}, $$ thus improving the previously best known bound of Jenssen, Joos and Perkins by a factor of $\log(3/2)/\log(9/8)+o(1)=3.442...$. Our proof is based on the novel approach from Jenssen, Joos and Perkins that uses the hard core sphere model of an appropriate fugacity. Similar constant-factor improvements in lower bounds are also obtained for general spherical codes, as well as for the expected density of random sphere packings in the Euclidean space $\mathbb Rd$.

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