Exclusion Volumes of Convex Bodies in High Space Dimensions: Applications to Virial Coefficients and Continuum Percolation

TL;DR

This paper derives an exact formula for the exclusion volume of convex bodies in any dimension using mixed volumes, revealing minimal and maximal shapes for exclusion volume and applying these to virial coefficients and continuum percolation thresholds.

Contribution

It introduces a general formula for exclusion volumes of convex bodies in high dimensions and analyzes their extremal properties, with applications to virial coefficients and percolation thresholds.

Findings

Sphere minimizes the dimensionless exclusion volume in all dimensions.

Simplex maximizes the exclusion volume asymptotically as dimension increases.

Overlapping spheres likely have the highest percolation threshold among convex bodies.

Abstract

Using the concepts of mixed volumes and quermassintegrals of convex geometry, we derive an exact formula for the exclusion volume for a general convex body that applies in any space dimension, including both the rotationally-averaged exclusion volume and with the same orientation. We show that the sphere minimizes the dimensionless exclusion volume $v_{ex}(K)/v(K)$ among all convex bodies, whether randomly oriented or uniformly oriented, for any $d$, where $v(K)$ is the volume of $K$. When the bodies have the same orientation, the simplex maximizes the dimensionless exclusion volume for any $d$ with a large-$d$ asymptotic scaling behavior of $2^{2d}/d^{3/2}$, which is to be contrasted with the scaling of $2^d$ for the sphere. We present explicit formulas for quermassintegrals for many nonspherical convex bodies as well as as well as lower-dimensional bodies. These results are utilized to determine the rotationally-averaged exclusion volume for these shapes for dimensions 2 through 12. While the sphere is the shape possessing the minimal dimensionless exclusion volume, among the convex bodies considered that are sufficiently compact, the simplex possesses the maximal dimensionless exclusion volume with a scaling behavior of $2^{1.6618\ldots d}$. We also determine the corresponding second virial coefficient $B_2(K)$ of the aforementioned hard hyperparticles and compute estimates of the continuum percolation threshold $\eta_c$ derived previously by the authors. We conjecture that overlapping spheres possess the maximal value of $\eta_c$ among all identical nonzero-volume convex overlapping bodies for $d \ge 2$, randomly or uniformly oriented, and that, among all identical, oriented nonzero-volume convex bodies, overlapping simplices have the minimal value of $\eta_c$ for $d\ge 2$.