Hypoelliptic Laplacian and Orbital Integrals (AM-177)

2011 ◽  
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.

A formula for semisimple orbital integrals

2011 ◽  
Author(s):  
Jean-Michel Bismut
Keyword(s):  
Heat Kernel ◽  
Explicit Formula ◽  
Wave Operator ◽  
Orbital Integrals ◽  
Gaussian Integral ◽  
Wave Kernel

This chapter states without proof the main result of this volume, which expresses the elliptic orbital integrals associated with the heat kernel as a Gaussian integral on t(γ‎). In addition, the chapter shows how to derive from this formula a corresponding formula for other kernels, which include the wave kernel. First, the chapter gives an explicit formula for the orbital integrals associated with the heat kernel of ℒAX in terms of a Gaussian integral on t(γ‎). From the formula for the heat kernel, this chapter derives a corresponding formula for the semisimple orbital integrals associated with the wave operator of ℒAX.

Introduction

2011 ◽  
Author(s):  
Jean-Michel Bismut
Keyword(s):  
Fixed Point ◽  
Riemannian Manifold ◽  
Trace Formula ◽  
Index Theory ◽  
Heat Kernels ◽  
Previous Literature ◽  
Orbital Integrals ◽  
Short Overview ◽  
History Of

This introductory chapter reviews the hypoelliptic Laplacian. It first explains how to mathematically conceive of a union between index theory and the trace formula through the Lefschetz fixed point formulas. The chapter then embarks on a brief history of the hypoelliptic Laplacian, hereafter turning to the construction of the hypoelliptic Laplacian that is carried out in this volume. Moreover, it discusses the analysis of the hypoelliptic orbital integrals, and its overlap with the analysis of the hypoelliptic Laplacian in previous literature, in which the Riemannian manifold X was assumed to be compact, and genuine traces or supertraces were considered. Here in this chapter X is noncompact, and the orbital integrals that appear are defined using explicit properties of the corresponding heat kernels. After this review, the chapter gives a short overview on the following chapters.

The heat kernel qb,tX for bounded b

2011 ◽  
Author(s):  
Jean-Michel Bismut
Keyword(s):  
Symmetric Space ◽  
Heat Kernel ◽  
Heat Kernels ◽  
Gaussian Type ◽  
Hypoelliptic Heat Kernel

This chapter establishes the estimates of a theorem discussed in Chapter 4 for the hypoelliptic heat kernel qb,tX((x,Y),(x′,Y′)) on ̂X. More precisely, this chapter shows that for bounded b > 0, the heat kernel verifies uniform Gaussian type estimates. Also, the limit is studied as b → 0 of this heat kernel. The method consists in using the techniques of chapters 12 and 13 for the scalar heat kernels over X and ̂X, and to control the kernel qb,tX by using a Feynman-Kac formula. In particular, the contribution of the representation ρ‎ᴱ is obtained by using results of chapter 12 applied to the symmetric space attached to the complexification K C of K.

scholarly journals On a singular Riemann–Liouville fractional boundary value problem with parameters

2021 ◽  
Vol 26 (1) ◽  
pp. 151-168
Author(s):  
Alexandru Tudorache ◽  
Rodica Luca
Keyword(s):  
Fixed Point ◽  
Fixed Point Index ◽  
Nonlocal Boundary ◽  
Index Theory ◽  
Nonlocal Boundary Conditions ◽  
Principal Characteristic ◽  
Fixed Point Index Theory ◽  
Existence Of Positive Solutions ◽  
Semipositone Problem ◽  
Fractional Differential

We investigate the existence of positive solutions for a nonlinear Riemann–Liouville fractional differential equation with a positive parameter subject to nonlocal boundary conditions, which contain fractional derivatives and Riemann–Stieltjes integrals. The nonlinearity of the equation is nonnegative, and it may have singularities at its variables. In the proof of the main results, we use the fixed point index theory and the principal characteristic value of an associated linear operator. A related semipositone problem is also studied by using the Guo–Krasnosel’skii fixed point theorem.

The displacement function and the return map

2011 ◽  
Author(s):  
Jean-Michel Bismut
Keyword(s):  
Fixed Point ◽  
Tangent Bundle ◽  
Geodesic Flow ◽  
Displacement Function ◽  
Semisimple Element ◽  
Fixed Point Set ◽  
Critical Set ◽  
Quantitative Estimates ◽  
Point Set ◽  
Toponogov’S Theorem

This chapter studies the displacement function dᵧ on X that is associated with a semisimple element γ‎ ∈ G. If φ‎″, t ∈ R denotes the geodesic flow on the total space X of the tangent bundle of X, the critical set X(γ‎) ⊂ X of dᵧ can be easily related to the fixed point set Fᵧ ⊂ X of the symplectic transformation γ‎⁻¹φ‎₁ of X. The chapter studies the nondegeneracy of γ‎⁻¹φ‎₁ − 1 along Fᵧ. More fundamentally, this chapter gives important quantitative estimates on how much φ‎ ½ differs from φ‎ ˗½γ‎ away from Fᵧ. These quantitative estimates are based on Toponogov's theorem.

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