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Bibliographic Details
Main Author: Braun, Mathias
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.16525
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_version_ 1866909560947605504
author Braun, Mathias
author_facet Braun, Mathias
contents We refine a recent distributional notion of d'Alembertian of a signed Lorentz distance function to an achronal set in a metric measure spacetime obeying the timelike measure contraction property. We show precise representation formulas and comparison estimates (both upper and lower bounds). Under a condition we call "infinitesimally strict concavity" (known for infinitesimally Minkowskian structures and established here for Finsler spacetimes), we prove the associated distribution is a signed measure certifying the integration by parts formula. This treatment of the d'Alembertian using techniques from metric geometry expands upon its recent nonlinear yet elliptic interpretation; even in the smooth case, our formulas seem to pioneer its exact shape across the timelike cut locus. Two central ingredients our contribution unifies are the localization paradigm of Cavalletti-Mondino and the Sobolev calculus of Beran-Braun-Calisti-Gigli-McCann-Ohanyan-Rott-Sämann. In the second part of our work, we present several applications of these insights. First, we show the equivalence of the timelike curvature-dimension condition with a Bochner-type inequality. Second, we set up synthetic mean curvature (as well as barriers for CMC sets) exactly. Third, we prove synthetic volume and area estimates of Heintze-Karcher-type, which enable us to show several synthetic volume singularity theorems.
format Preprint
id arxiv_https___arxiv_org_abs_2408_16525
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Exact d'Alembertian for Lorentz distance functions
Braun, Mathias
Differential Geometry
General Relativity and Quantum Cosmology
Mathematical Physics
Metric Geometry
28A50, 51K10 (Primary), 35J92, 49Q22, 51F99, 53C21, 53C50, 83C75 (Secondary)
We refine a recent distributional notion of d'Alembertian of a signed Lorentz distance function to an achronal set in a metric measure spacetime obeying the timelike measure contraction property. We show precise representation formulas and comparison estimates (both upper and lower bounds). Under a condition we call "infinitesimally strict concavity" (known for infinitesimally Minkowskian structures and established here for Finsler spacetimes), we prove the associated distribution is a signed measure certifying the integration by parts formula. This treatment of the d'Alembertian using techniques from metric geometry expands upon its recent nonlinear yet elliptic interpretation; even in the smooth case, our formulas seem to pioneer its exact shape across the timelike cut locus. Two central ingredients our contribution unifies are the localization paradigm of Cavalletti-Mondino and the Sobolev calculus of Beran-Braun-Calisti-Gigli-McCann-Ohanyan-Rott-Sämann. In the second part of our work, we present several applications of these insights. First, we show the equivalence of the timelike curvature-dimension condition with a Bochner-type inequality. Second, we set up synthetic mean curvature (as well as barriers for CMC sets) exactly. Third, we prove synthetic volume and area estimates of Heintze-Karcher-type, which enable us to show several synthetic volume singularity theorems.
title Exact d'Alembertian for Lorentz distance functions
topic Differential Geometry
General Relativity and Quantum Cosmology
Mathematical Physics
Metric Geometry
28A50, 51K10 (Primary), 35J92, 49Q22, 51F99, 53C21, 53C50, 83C75 (Secondary)
url https://arxiv.org/abs/2408.16525