Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /

Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /

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Our DMV Seminar on 'Classical Nonintegrability, Quantum Chaos' intended to introduce students and beginning researchers to the techniques applied in nonin­ tegrable classical and quantum dynamics. Several of these lectures are collected in this volume. The basic phenomenon of nonlinear dynamics is mixing in phase space, lead­ ing to a positive dynamical entropy and a loss of information about the initial state. The nonlinear motion in phase space gives rise to a linear action on phase space functions which in the case of iterated maps is given by a so-called transfer operator. Good mixing rates lead to a spectral gap for this operator. Similar to the use made of the Riemann zeta function in the investigation of the prime numbers, dynamical zeta functions are now being applied in nonlinear dynamics. In Chapter 2 V. Baladi first introduces dynamical zeta functions and transfer operators, illustrating and motivating these notions with a simple one-dimensional dynamical system. Then she presents a commented list of useful references, helping the newcomer to enter smoothly into this fast-developing field of research. Chapter 3 on irregular scattering and Chapter 4 on quantum chaos by A. Knauf deal with solutions of the Hamilton and the Schr6dinger equation. Scatter­ ing by a potential force tends to be irregular if three or more scattering centres are present, and a typical phenomenon is the occurrence of a Cantor set of bounded orbits. The presence of this set influences those scattering orbits which come close.

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Main Authors: Knauf, Andreas. author., Sinai, Yakov G. author., Baladi, Viviane. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Basel : Birkhäuser Basel : Imprint: Birkhäuser, 1997
Subjects:Physics., Mathematical physics., Elementary particles (Physics)., Quantum field theory., Elementary Particles, Quantum Field Theory., Mathematical Physics., Mathematical Methods in Physics.,
Online Access:http://dx.doi.org/10.1007/978-3-0348-8932-2
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id KOHA-OAI-TEST:195967
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Physics.
Mathematical physics.
Elementary particles (Physics).
Quantum field theory.
Physics.
Elementary Particles, Quantum Field Theory.
Mathematical Physics.
Mathematical Methods in Physics.
Physics.
Mathematical physics.
Elementary particles (Physics).
Quantum field theory.
Physics.
Elementary Particles, Quantum Field Theory.
Mathematical Physics.
Mathematical Methods in Physics.
spellingShingle Physics.
Mathematical physics.
Elementary particles (Physics).
Quantum field theory.
Physics.
Elementary Particles, Quantum Field Theory.
Mathematical Physics.
Mathematical Methods in Physics.
Physics.
Mathematical physics.
Elementary particles (Physics).
Quantum field theory.
Physics.
Elementary Particles, Quantum Field Theory.
Mathematical Physics.
Mathematical Methods in Physics.
Knauf, Andreas. author.
Sinai, Yakov G. author.
Baladi, Viviane. author.
SpringerLink (Online service)
Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /
description Our DMV Seminar on 'Classical Nonintegrability, Quantum Chaos' intended to introduce students and beginning researchers to the techniques applied in nonin­ tegrable classical and quantum dynamics. Several of these lectures are collected in this volume. The basic phenomenon of nonlinear dynamics is mixing in phase space, lead­ ing to a positive dynamical entropy and a loss of information about the initial state. The nonlinear motion in phase space gives rise to a linear action on phase space functions which in the case of iterated maps is given by a so-called transfer operator. Good mixing rates lead to a spectral gap for this operator. Similar to the use made of the Riemann zeta function in the investigation of the prime numbers, dynamical zeta functions are now being applied in nonlinear dynamics. In Chapter 2 V. Baladi first introduces dynamical zeta functions and transfer operators, illustrating and motivating these notions with a simple one-dimensional dynamical system. Then she presents a commented list of useful references, helping the newcomer to enter smoothly into this fast-developing field of research. Chapter 3 on irregular scattering and Chapter 4 on quantum chaos by A. Knauf deal with solutions of the Hamilton and the Schr6dinger equation. Scatter­ ing by a potential force tends to be irregular if three or more scattering centres are present, and a typical phenomenon is the occurrence of a Cantor set of bounded orbits. The presence of this set influences those scattering orbits which come close.
format Texto
topic_facet Physics.
Mathematical physics.
Elementary particles (Physics).
Quantum field theory.
Physics.
Elementary Particles, Quantum Field Theory.
Mathematical Physics.
Mathematical Methods in Physics.
author Knauf, Andreas. author.
Sinai, Yakov G. author.
Baladi, Viviane. author.
SpringerLink (Online service)
author_facet Knauf, Andreas. author.
Sinai, Yakov G. author.
Baladi, Viviane. author.
SpringerLink (Online service)
author_sort Knauf, Andreas. author.
title Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /
title_short Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /
title_full Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /
title_fullStr Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /
title_full_unstemmed Classical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi /
title_sort classical nonintegrability, quantum chaos [electronic resource] : with a contribution by viviane baladi /
publisher Basel : Birkhäuser Basel : Imprint: Birkhäuser,
publishDate 1997
url http://dx.doi.org/10.1007/978-3-0348-8932-2
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AT springerlinkonlineservice classicalnonintegrabilityquantumchaoselectronicresourcewithacontributionbyvivianebaladi
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spelling KOHA-OAI-TEST:1959672018-07-30T23:21:34ZClassical Nonintegrability, Quantum Chaos [electronic resource] : With a contribution by Viviane Baladi / Knauf, Andreas. author. Sinai, Yakov G. author. Baladi, Viviane. author. SpringerLink (Online service) textBasel : Birkhäuser Basel : Imprint: Birkhäuser,1997.engOur DMV Seminar on 'Classical Nonintegrability, Quantum Chaos' intended to introduce students and beginning researchers to the techniques applied in nonin­ tegrable classical and quantum dynamics. Several of these lectures are collected in this volume. The basic phenomenon of nonlinear dynamics is mixing in phase space, lead­ ing to a positive dynamical entropy and a loss of information about the initial state. The nonlinear motion in phase space gives rise to a linear action on phase space functions which in the case of iterated maps is given by a so-called transfer operator. Good mixing rates lead to a spectral gap for this operator. Similar to the use made of the Riemann zeta function in the investigation of the prime numbers, dynamical zeta functions are now being applied in nonlinear dynamics. In Chapter 2 V. Baladi first introduces dynamical zeta functions and transfer operators, illustrating and motivating these notions with a simple one-dimensional dynamical system. Then she presents a commented list of useful references, helping the newcomer to enter smoothly into this fast-developing field of research. Chapter 3 on irregular scattering and Chapter 4 on quantum chaos by A. Knauf deal with solutions of the Hamilton and the Schr6dinger equation. Scatter­ ing by a potential force tends to be irregular if three or more scattering centres are present, and a typical phenomenon is the occurrence of a Cantor set of bounded orbits. The presence of this set influences those scattering orbits which come close.1 Introduction -- 2 Dynamical Zeta Functions -- 2.1 Introduction and Motivation -- 2.2 Commented Bibliography -- 3 Irregular Scattering -- 3.1 Notions of Classical Potential Scattering -- 3.2 Centrally Symmetric Potentials -- 3.3 Scattering by Convex Obstacles -- 3.4 Symbolic Dynamics -- 3.5 Irregular Scattering by Potentials -- 3.6 Time Delay and the Differential Cross Section -- 4 Quantum Chaos -- 4.1 Husimi Functions -- 4.2 Pseudodifferential Operators -- 4.3 Fourier Integral Operators -- 4.4 The Schnirelman Theorem -- 4.5 Further Directions -- 5 Ergodicity and Mixing -- 6 Expanding Maps -- 7 Liouville Surfaces -- Participants -- Additional Talks.Our DMV Seminar on 'Classical Nonintegrability, Quantum Chaos' intended to introduce students and beginning researchers to the techniques applied in nonin­ tegrable classical and quantum dynamics. Several of these lectures are collected in this volume. The basic phenomenon of nonlinear dynamics is mixing in phase space, lead­ ing to a positive dynamical entropy and a loss of information about the initial state. The nonlinear motion in phase space gives rise to a linear action on phase space functions which in the case of iterated maps is given by a so-called transfer operator. Good mixing rates lead to a spectral gap for this operator. Similar to the use made of the Riemann zeta function in the investigation of the prime numbers, dynamical zeta functions are now being applied in nonlinear dynamics. In Chapter 2 V. Baladi first introduces dynamical zeta functions and transfer operators, illustrating and motivating these notions with a simple one-dimensional dynamical system. Then she presents a commented list of useful references, helping the newcomer to enter smoothly into this fast-developing field of research. Chapter 3 on irregular scattering and Chapter 4 on quantum chaos by A. Knauf deal with solutions of the Hamilton and the Schr6dinger equation. Scatter­ ing by a potential force tends to be irregular if three or more scattering centres are present, and a typical phenomenon is the occurrence of a Cantor set of bounded orbits. The presence of this set influences those scattering orbits which come close.Physics.Mathematical physics.Elementary particles (Physics).Quantum field theory.Physics.Elementary Particles, Quantum Field Theory.Mathematical Physics.Mathematical Methods in Physics.Springer eBookshttp://dx.doi.org/10.1007/978-3-0348-8932-2URN:ISBN:9783034889322

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