Book contents
- Frontmatter
- Contents
- List of contributors
- Preface to the paperback edition
- Preface to the first edition
- 0 A guided tour through the book
- 1 Wavelet analysis: a new tool in physics
- 2 The 2-D wavelet transform, physical applications and generalizations
- 3 Wavelets and astrophysical applications
- 4 Turbulence analysis, modelling and computing using wavelets
- 5 Wavelets and detection of coherent structures in fluid turbulence
- 6 Wavelets, non-linearity and turbulence in fusion plasmas
- 7 Transfers and fluxes of wind kinetic energy between orthogonal wavelet components during atmospheric blocking
- 8 Wavelets in atomic physics and in solid state physics
- 9 The thermodynamics of fractals revisited with wavelets
- 10 Wavelets in medicine and physiology
- 11 Wavelet dimensions and time evolution
- Index
8 - Wavelets in atomic physics and in solid state physics
Published online by Cambridge University Press: 27 January 2010
- Frontmatter
- Contents
- List of contributors
- Preface to the paperback edition
- Preface to the first edition
- 0 A guided tour through the book
- 1 Wavelet analysis: a new tool in physics
- 2 The 2-D wavelet transform, physical applications and generalizations
- 3 Wavelets and astrophysical applications
- 4 Turbulence analysis, modelling and computing using wavelets
- 5 Wavelets and detection of coherent structures in fluid turbulence
- 6 Wavelets, non-linearity and turbulence in fusion plasmas
- 7 Transfers and fluxes of wind kinetic energy between orthogonal wavelet components during atmospheric blocking
- 8 Wavelets in atomic physics and in solid state physics
- 9 The thermodynamics of fractals revisited with wavelets
- 10 Wavelets in medicine and physiology
- 11 Wavelet dimensions and time evolution
- Index
Summary
Abstract
In the field of atomic and solid state physics, wavelet analysis has been applied so far in three different directions: (i) time-frequency analysis of harmonic generation in laser-atom interactions; (ii) ab initio electronic structure calculations in atoms and molecules; and (iii) construction of localized bases for the lowest Landau level of a 2-D electron gas submitted to a strong magnetic field. We survey these three types of applications, with more emphasis on methods than on precise results.
Introduction
There are two ways in which wavelets could play a role in atomic physics and possibly in solid state physics.
First one may envisage them as physical objects, namely quantum states or wave functions. It is commonplace to remark that coherent states (CS) have a privileged role in atomic physics. Laser-atom interactions, revival phenomena, Rydberg wave packets and various semi-classical situations are all instances in which a coherent state description is clearly well-adapted. Of course, what is implied here are canonical CS, associated to the harmonic oscillator or the electromagnetic field [36]. But wavelets are also coherent states, namely those associated to the affine groups in various space dimensions, as we have seen in Chapter 2 (see [1] for a review on coherent states). Thus wavelets could well be thought of as convenient substitutes for canonical CS. However, this suggestion is still speculative at the present moment, very little has been achieved in this direction.
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- Wavelets in Physics , pp. 299 - 338Publisher: Cambridge University PressPrint publication year: 1999
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