The heat kernel on asymptotically hyperbolic manifolds

Upper and lower bounds on the heat kernel on complete Riemannian manifolds were obtained in a series of pioneering works due to Cheng-Li-Yau, Cheeger-Yau and Li-Yau. However, these estimates do not give a complete picture of the heat kernel for all times and all pairs of points - in particular, ther...

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Bibliographic Details
Published in:Communications in partial differential equations 2020-09, Vol.45 (9), p.1031-1071
Main Authors: Chen, Xi, Hassell, Andrew
Format: Article
Language:English
Subjects:
Asymptotic properties
Asymptotically hyperbolic manifolds
Eigenvalues
Euclidean geometry
heat kernel
Kernels
Lower bounds
Manifolds (mathematics)
resolvent
Riemann manifold
Riesz transform
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Summary:Upper and lower bounds on the heat kernel on complete Riemannian manifolds were obtained in a series of pioneering works due to Cheng-Li-Yau, Cheeger-Yau and Li-Yau. However, these estimates do not give a complete picture of the heat kernel for all times and all pairs of points - in particular, there is a considerable gap between available upper and lower bounds at large distances and/or large times. Inspired by the work of Davies-Mandouvalos on we study heat kernel bounds on Cartan-Hadamard manifolds that are asymptotically hyperbolic in the sense of Mazzeo-Melrose. Under the assumption of no eigenvalues and no resonance at the bottom of the continuous spectrum, we show that the heat kernel on such manifolds is comparable to the heat kernel on hyperbolic space of the same dimension (expressed as a function of time t and geodesic distance r), uniformly for all and all In particular our upper and lower bounds are uniformly comparable for all distances and all times. The corresponding statement for asymptotically Euclidean spaces is not known to hold, and as we argue in the last section, it is very unlikely to be true in that geometry. As an application, we show boundedness on L p of the Riesz transform for on such manifolds, for p satisfying For (the standard Riesz transform ), this was previously shown by Lohoué in a more general setting.
ISSN:0360-5302
1532-4133
DOI:10.1080/03605302.2020.1750425