II: Fourier Analysis, Self-Adjointness, Volume 2This volume will serve several purposes: to provide an introduction for graduate students not previously acquainted with the material, to serve as a reference for mathematical physicists already working in the field, and to provide an introduction to various advanced topics which are difficult to understand in the literature. Not all the techniques and application are treated in the same depth. In general, we give a very thorough discussion of the mathematical techniques and applications in quatum mechanics, but provide only an introduction to the problems arising in quantum field theory, classical mechanics, and partial differential equations. Finally, some of the material developed in this volume will not find applications until Volume III. For all these reasons, this volume contains a great variety of subject matter. To help the reader select which material is important for him, we have provided a "Reader's Guide" at the end of each chapter. |
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Contents
The Fourier transform on R and SR convolutions | 1 |
Commutative Banach Algebras | 114 |
SELFADJOINTNESS AND THE EXISTENCE OF DYNAMICS 1 Extensions of symmetric operators | 135 |
Appendix Motion on a halfline limit pointlimit circle methods | 146 |
Perturbations of selfadjoint operators | 162 |
Quadratic forms | 176 |
Pointwise positivity | 182 |
The commutator theorem | 191 |
Applications to Quantum Field Theory | 266 |
Graph Limits | 268 |
The FeynmanKac formula | 274 |
Timedependent Hamiltonians | 282 |
Classical nonlinear wave equations | 293 |
The Hilbert space approach to classical mechanics | 313 |
Notes | 318 |
Applications to Statistical Mechanics | 327 |
Analytic vectors | 200 |
Free quantum fields | 207 |
Von Neumann Algebras | 227 |
Appendix The Weyl relations for the free field | 231 |
Semigroups and their generators | 235 |
Hypercontractive semigroups | 258 |
Problems | 338 |
Readers Guide | 349 |
353 | |
355 | |
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Common terms and phrases
accretive adjoint analytic vector argument Banach space C₁ classical commutation compact support conclude cone constant continuous function contraction semigroup converges Corollary d²/dx² deficiency indices define denote differential operators discussion domain essentially self-adjoint Example exists finite follows formula Fourier transform Friedrichs extension Hamiltonian Hilbert space hypercontractive hypotheses implies inequality infinity integral interpolation theorem invariant K₁ Kato-Rellich theorem Ľ²(R lemma linear Math measure norm partial differential equations Phys Plancherel theorem polynomially bounded positivity preserving Problem Proof Let proof of Theorem properties Proposition prove quadratic form quantum field theory quantum mechanics real-valued representation Riesz-Thorin theorem satisfies scalar Schrödinger self-adjoint extension self-adjoint operator semigroup singular Sobolev's solution strongly continuous supp Suppose symmetric operator T₁ tempered distribution uniformly bounded unique V₁ V₂ WF(T Wightman axioms zero