2021
DOI: 10.48550/arxiv.2103.02744
|View full text |Cite
Preprint
|
Sign up to set email alerts
|

The Positive Mass Theorem with Arbitrary Ends

Abstract: We prove a Riemannian positive mass theorem for manifolds with a single asymptotically flat end, but otherwise arbitrary other ends, which can be incomplete and contain negative scalar curvature. The incompleteness and negativity is compensated for by large positive scalar curvature on an annulus, in a quantitative fashion. In the complete noncompact case with nonnegative scalar curvature, we have no extra assumption and hence prove a long-standing conjecture of Schoen and Yau. Contents 1. Introduction 1 2. Th… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
5

Citation Types

0
12
0

Year Published

2021
2021
2023
2023

Publication Types

Select...
3
2

Relationship

0
5

Authors

Journals

citations
Cited by 5 publications
(12 citation statements)
references
References 34 publications
0
12
0
Order By: Relevance
“…The value of the number R(E, g) > 0 appearing in Theorem A could in principle be traced through our proof but it crucially depends on the constant in a weighted Poincaré inequality on the chosen asymptotically Euclidean end and thus it appears difficult to make explicit. Note that Lesourd, Unger, and Yau have also established a quantitative theorem in their approach to Conjecture 1.2 which involves more explicit estimates; see [18,Theorem 1.6]. However, unlike our Theorem A, their quantitative theorem relies on a largeness assumption on the scalar curvature which forces it to be strictly positive in a certain region.…”
Section: Introduction and Main Resultsmentioning
confidence: 97%
See 4 more Smart Citations
“…The value of the number R(E, g) > 0 appearing in Theorem A could in principle be traced through our proof but it crucially depends on the constant in a weighted Poincaré inequality on the chosen asymptotically Euclidean end and thus it appears difficult to make explicit. Note that Lesourd, Unger, and Yau have also established a quantitative theorem in their approach to Conjecture 1.2 which involves more explicit estimates; see [18,Theorem 1.6]. However, unlike our Theorem A, their quantitative theorem relies on a largeness assumption on the scalar curvature which forces it to be strictly positive in a certain region.…”
Section: Introduction and Main Resultsmentioning
confidence: 97%
“…However, the last remaining cases of the Liouville theorem have recently been proved through a combination of preprints by Chodosh and Li [7] and Lesourd, Unger, and Yau [17], but without addressing Conjecture 1.2. Instead, in a separate more recent preprint, Lesourd, Unger, and Yau [18] proved Conjecture 1.2 for n ≤ 7 assuming that the chosen end E satisfies a more specific fall-off condition, namely that it is asymptotic to Schwarzschild (compare Example 2.2). In the classical case of Theorem 1.1, more general fall-off conditions can be reduced to Schwarzschild asymptotics via a density theorem, but at the moment this does not appear to be readily available in the setting of arbitrary ends as pointed out in [18].…”
Section: Introduction and Main Resultsmentioning
confidence: 99%
See 3 more Smart Citations