Global Gaussian Estimates for the Heat Kernel of Homogeneous Sums of Squares

AbstractLet 0 < wbe a smooth function on a complete Riemannian manifold Mn, and define L = — Δ — ▽ (log w) and Rw =Ric - w -1 Hess w.In this paper we show that if Rw ≥ —nK, (K ≥0), then the positive solutions of (L + ∂/∂t)u —0 satisfy a gradient estimate of the same form as that obtained by Li and Yau ([LY]) when Lis the Laplacian. This is used to obtain a parabolic Harnack inequality, which in turn, yields upper and lower Gaussian estimates for the heat kernel of L.The results obtained are applied to study the LPmapping properties of t→ e-tL μfor measures μ which are α-dimensional in a sense that generalises the local uniform α-dimensionality introduced by R. S. Strichartz ([St2], [St3]).

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Generalized Gaussian estimates and riesz means of Schrödinger groups

Journal of the Australian Mathematical Society ◽

10.1017/s1446788700016001 ◽

2007 ◽

Vol 82 (2) ◽

pp. 149-162 ◽

Cited By ~ 7

Author(s):

Sönke Blunck

Keyword(s):

Heat Kernel ◽

Lower Order ◽

Higher Order ◽

Elliptic Operators ◽

Riesz Means ◽

Lower Order Terms ◽

Selfadjoint Semigroups ◽

Gaussian Estimates

AbstractWe show that generalized Gaussian estimates for selfadjoint semigroups (e-tA)t ∈ R+ on L2 imply Lp boundedness of Riesz means and other regularizations of the Schrödinger group (eitA)t ∈ R. This generalizes results restricted to semigroups with a heat kernel, which are due to Sjöstrand, Alexopoulos and more recently Carron, Coulhon and Ouhabaz. This generalization is crucial for elliptic operators A that are of higher order or have singular lower order terms since, in general, their semigroups fail to have a heat kernel.

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Sums of Squares and Triangular Numbers

Online Journal of Analytic Combinatorics ◽

10.15852/ojac001.a.01 ◽

2006 ◽

Cited By ~ 2

Author(s):

Hershel Farkas

Keyword(s):

Sums Of Squares ◽

Triangular Numbers

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The Resolvent Operator

10.23943/princeton/9780691157122.003.0011 ◽

2017 ◽

Author(s):

Charles L. Epstein ◽

Rafe Mazzeo

Keyword(s):

Cauchy Problem ◽

Heat Equation ◽

Laplace Transform ◽

Heat Kernel ◽

Resolvent Operator ◽

Contour Integration ◽

Resolvent Kernel ◽

The Laplace Transform ◽

Elliptic Estimates ◽

The Resolvent Operator

This chapter describes the construction of a resolvent operator using the Laplace transform of a parametrix for the heat kernel and a perturbative argument. In the equation (μ‎-L) R(μ‎) f = f, R(μ‎) is a right inverse for (μ‎-L). In Hölder spaces, these are the natural elliptic estimates for generalized Kimura diffusions. The chapter first constructs the resolvent kernel using an induction over the maximal codimension of bP, and proves various estimates on it, along with corresponding estimates for the solution operator for the homogeneous Cauchy problem. It then considers holomorphic semi-groups and uses contour integration to construct the solution to the heat equation, concluding with a discussion of Kimura diffusions where all coefficients have the same leading homogeneity.

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Hypoelliptic Laplacian and Orbital Integrals (AM-177)

10.23943/princeton/9780691151298.001.0001 ◽

2011 ◽

Cited By ~ 5

Author(s):

Jean-Michel Bismut

Keyword(s):

Fixed Point ◽

Symmetric Space ◽

Heat Kernel ◽

Geodesic Flow ◽

Casimir Operator ◽

Index Theory ◽

Weighted Sum ◽

Orbital Integrals ◽

Hypoelliptic Heat Kernel ◽

Wave Kernel

This book uses the hypoelliptic Laplacian to evaluate semisimple orbital integrals in a formalism that unifies index theory and the trace formula. The hypoelliptic Laplacian is a family of operators that is supposed to interpolate between the ordinary Laplacian and the geodesic flow. It is essentially the weighted sum of a harmonic oscillator along the fiber of the tangent bundle, and of the generator of the geodesic flow. In this book, semisimple orbital integrals associated with the heat kernel of the Casimir operator are shown to be invariant under a suitable hypoelliptic deformation, which is constructed using the Dirac operator of Kostant. Their explicit evaluation is obtained by localization on geodesics in the symmetric space, in a formula closely related to the Atiyah-Bott fixed point formulas. Orbital integrals associated with the wave kernel are also computed. Estimates on the hypoelliptic heat kernel play a key role in the proofs, and are obtained by combining analytic, geometric, and probabilistic techniques. Analytic techniques emphasize the wavelike aspects of the hypoelliptic heat kernel, while geometrical considerations are needed to obtain proper control of the hypoelliptic heat kernel, especially in the localization process near the geodesics. Probabilistic techniques are especially relevant, because underlying the hypoelliptic deformation is a deformation of dynamical systems on the symmetric space, which interpolates between Brownian motion and the geodesic flow. The Malliavin calculus is used at critical stages of the proof.

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