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Singular Quadratic Forms in Perturbation Theory PDF

315 Pages·1999·10.244 MB·English
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Singular Quadratic Fonns in Perturbation Theory Mathematics and Its Applications Managing Editor: M.HAZEWINKEL Centre for Mathematics and Computer Science, Amsterdam, The Netherlands Volume 474 Singular Quadratic Forms in Perturbation Theory by Volodymyr Koshmanenko Institute of Mathematics, National Academy of Sciences, Kiev, Ukraine SPRINGER-SCIENCE+BUSINESS MEDIA, B.V. A C.I.P. Catalogue record for this book is available from the Library of Congress. ISBN 978-94-010-5952-7 ISBN 978-94-011-4619-7 (eBook) DOI 10.1007/978-94-011-4619-7 Printed on acid-free paper This is a completely revised and updated translation of the original Russian work Singular Bilinear Forms in Perturbation Theory of Self-Adjoint Operators, Kiev, Naukova Dumka, ©1993. Translated by P.V. Malyshev and D.V. Malyshev. All Rights Reserved © 1999 Springer Science+Business Media Dordrecht Originally published by Kluwer Academic Publishers in 1999 Softcover reprint of the hardcover 1s t edition 1999 No part of the material protected by this copyright notice may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying, recording or by any information storage and retrieval system, without written permission from the copyright owner conTEnTS Preface to the English Edition vii Introduction 1 Chapter 1. QUADRATIC FORMS AND LINEAR OPERATORS 5 1. Preliminary Facts about Quadratic Forms 5 2. Closed and Closable Quadratic Forms 16 3. Operator Representations of Quadratic Forms 31 4. Quadratic Forms in the Theory of Self-Adjoint Extensions of Symmetric Operators 47 Chapter 2. SINGULAR QUADRATIC FORMS 59 5. Definition of Singular Quadratic Forms 60 6. Properties of Singular Quadratic Forms 74 7. Operator Representation of Singular Quadratic Forms 81 8. Singular Quadratic Forms in the A-Scale of Hilbert Spaces 87 9. Regularization 102 Chapter 3. SINGULAR PERTURBATIONS OF SELF -ADJOINT OPERATORS 123 lO. Rank-One Singular Perturbations 124 11. Singular Perturbations of Finite Rank 143 12. Method of Self-Adjoint Extensions 157 13. Powers of Singularly Perturbed Operators 172 14. Method of Orthogonal Extensions 191 15. Approximations 207 v vi Contents Chapter 4. APPLICATIONS TO QUANTUM FIELD THEORY 227 16. Singular Properties of Wick Monomials 227 17. Orthogonally Extended Fock Space 238 18. Scattering and Spectral Problems 254 REFERENCES 281 SUBJECT INDEX 305 NOTATION 307 PREFACE TO THE EnGLISH EDITIon The notion of singular quadratic form appears in mathematical physics as a tool for the investigation of formal expressions corresponding to perturbations devoid of operator sense. Numerous physical models are based on the use of Hamiltonians containing perturba tion terms with singular properties. Typical examples of such expressions are Schrodin ger operators with O-potentials (-~ + AD) and Hamiltonians in quantum field theory with perturbations given in terms of operators of creation and annihilation (P( <p )-mod els ). Traditional approaches to the solution of problems of this kind are based on the idea of approximation of a singular expression corresponding to a give:n perturbation by a sequence of regularized perturbations. This approach is inevitably connected with vari ous ambiguities and divergences. In a certain sense, these problems are solved by renor malization theory, which, however, is too complicated. This explains the necessity in the development of other methods in the the theory of singular perturbations. In particular, the method of singular quadratic forms combined with the method of self-adjoint exten sions seems to be one of the most promising approaches. This monograph is, in fact, the first attempt of systematic presentation of the method of singular quadratic forms in the theory of perturbations of self-adjoint operators. A major part of the monograph is devoted to the detailed investigation of properties of singular quadratic forms, which are the key objects of the theory. We consider numer ous examples of such forms. We give a detailed presentation of several methods for the construction of a singularly perturbed operator, depending on the degree of singularity of a perturbation. As an application, we consider a model of a Hamiltonian of free quantum field in the Fock space with a perturbation given by singular Wick monomials. The author assumes that the reader is familiar with such branches of functional ana lysis and mathematical physics as the theory of linear operators in Hilbert spaces [AkG], the theory of perturbations of linear operators [Katl], the theory of quadratic forms [Katl], [ReS I], [ReS2], scattering theory [Katl], [ReS3], the theory of rigged Hilbert vii viii Preface to the English Edition spaces [Berl], [Ber2], the theory of self-adjoint extensions of Hermitian operators [AkG], [Kre2], and quantum field theory [BLT] and with the remarkable monograph [AGHKH], where numerous explicitly solvable models with singular perturbations are considered. The author expresses his deep gratitude to Prof. S. Albeverio, Prof. Yu. M. Berezan skii, Prof. L. P. Nizhnik, Prof. Yu. G. Kondratiev, Prof. W. Karwowski, Prof.H. Neid hardt, Prof. 1. F. Brasche, and Prof. S. 6ta for fruitful discussions helpful remarks, and collaboration. InTRODUCTIon The theory of perturbations of linear operators in Hilbert spaces is, in fact, a theory of additive perturbations in which a perturbed operator H is defined as the sum H = Ho + £ V of an operator Ho corresponding to the Hamiltonian of a free physical system and an operator V that describes interaction; £ is a coupling constant (see the fundamental monograph of Kato [Katl]). Assume that Ho and V are self-adjoint operators in a Hil bert space J{ which is the space of states of a physical system. The following problems are usually regarded as basic problems of perturbation theory: criteria of essential self adjointness of the operator H, the structure of the spectrum of H and its dependence on £ and the properties of V, the construction of the resolvent R z :: (H - z )-1 and the unitary group e-itH which describes the evolution of the physical system in time, and the existence of the wave operators W± (H, H 0) and the scattering matrix. The main difference between the theory of singular perturbations and the ordinary perturbation theory of linear operators is that singular perturbations cannot be regarded as additive. It is impossible to represent the perturbed operator in the form of a sum of the operator Ho and the operator that describes interaction. In fact, singular perturbations correspond to changes in boundary conditions (in an abstract sense). Singular perturba tions are usually concentrated on subsets of Lebesgue measure zero and, therefore, are equal to zero in dense domains in J{. Consequently, they do not possess the ordinary operator representation. At the same time, they are well described in terms of (nonclos able and singular) quadratic forms. The notion of singular quadratic forms is the key object of the present monograph. Roughly speaking, singularity means that the quadratic form is not closed anywhere in J{ (see Definition 2.l.2). In practice, this property takes place if the form is equal to zero in a dense domain in the space J{. In general, any densely defined Hermitian quad ratic form 'Y bounded from below admits the canonical expansion Y= 'Yr + 'Ys into regu lar (= closed) and singular (= everywhere nonclosed) components (see [Sim4] and [Kos3]). Here, we mainly consider the case of pure singular perturbations, i.e., 'Y = 'Ys. A typical example of a problem with singular perturbations is given by the following model: the Schrodinger operator - ~ + £C) with C)-potential. Very many publications are devoted to the investigation of this model and its various modifications and versions (see the monograph by Albeverio, Gesztezy, H~egh-Krohn, and Holden [AGHKH] and de tailed bibliography therein). In the present monograph, we develop abstract approaches to the study of singular perturbations based on the notion of quadratic forms. V. Koshmanenko, Singular Quadratic Forms in Perturbation Theory © Springer Science+Business Media Dordrecht 1999 2 Introduction In general, there are many ways of taking into account the effect of singular perturbation. The method of quadratic forms, the method of self-adjoint extensions, and the method of orthogonal extensions are among the most extensively used methods of this kind. They are applied and developed in the present monograph. We now briefly describe the essence of each of these methods. Assume that A is a positive self-adjoint operator (the Hamiltonian of free physical system) with the domain of definition V(A) given in a Hilbert space Ji. Its perturba tion is defined as a singular Hermitian quadratic form y with the domain of definition n Q (y). The singularity of y means that the set V = (Ker y) V(A) is dense in Ji. It is required to construct and investigate the properties of the self-adjoint operator Ay that corresponds to the Hamiltonian of the perturbed system. It is natural that the operators A and Ay must coincide in V, i.e., Consequently, if Ay exists, then it is a self-adjoint extension of the symmetric operator Thus, Ay"# A + V for any closed linear operator V in Ji because, otherwise, V must be equal to zero in the dense set V. The choice of methods used for the construction of the perturbed operator Ay as well as the possibility of this construction depend on the degree of singularity of the perturbation y. A natural classification of the degrees of singularity of the quadratic form y as a perturbation of the operator A appears in the scale of Hilbert spaces associated with A (A-scale) where Jik = V(A k/2) in the graph norm. In the present monograph, we do not consider the case of regular perturbations, where the form y is densely defined, bounded from below, and closed in Ji from the domain V(A)n Q(y). We say that a form y determines a perturbation from the Ji_, (A)-class if it is bounded from below and closed in the space Ji, and, moreover, if the set V = n (Kery) V(A) is dense in Ji. In this case, y generates a self-adjoint operator V that acts from Ji, into Ji_,. In the present monograph, we consider positive forms and forms of finite ranks. For perturbations from the class Ji_, (A), it is customary to use the method of quad ratic forms, which is fairly well developed and have many applications (see, e.g., [AGHKH, AGS, Ber3, BeK, Chu, DaS, DeO, Fra, GeS, G11, KiS, KosS, KosI3, KosI6, KosI8-Kos22, LyM, Mik, Nen3, Seg, Shal, Sha2, SimI-SimS, StovI, Stov2, Tip, and

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