Proves Wasserstein inequality bounding transport cost by Green's function sum, implying optimal W2 rate for minimal Green energy point sets on manifolds and Coulomb energy on spheres.
Discrepancy of minimal Riesz energy points
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abstract
We find upper bounds for the spherical cap discrepancy of the set of minimizers of the Riesz $s$-energy on the sphere $\mathbb S^d.$ Our results are based in bounds for a Sobolev discrepancy introduced by Thomas Wolff in an unpublished manuscript where estimates for the spherical cap discrepancy of the logarithmic energy minimizers in $\mathbb S^2$ were obtained. Our result improves previously known bounds for $0\le s<2$ and $s\neq 1$ in $\mathbb S^2,$ where $s=0$ is Wolff's result, and for $d-t_0<s<d$ with $t_0\approx 2.5$ when $d\ge 3$ and $s\neq d-1.$
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math.CA 1years
2019 1verdicts
UNVERDICTED 1representative citing papers
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A Wasserstein Inequality and Minimal Green Energy on Compact Manifolds
Proves Wasserstein inequality bounding transport cost by Green's function sum, implying optimal W2 rate for minimal Green energy point sets on manifolds and Coulomb energy on spheres.