Marl, : Verband alter KVer e.V., 1954-

Online-Ressource

1

370

Zeitschrift

Tedesco

Gesehen am 01.04.11

Weinheim ; ; [Cambridge], : Wiley-VCH, c2004

9786611764715

9781281764713

128176471X

9783527602520

3527602526

9783527621019

3527621016

1 online resource (342 p.)

SuraudEric

539.7

Cluster theory (Nuclear physics)

Inglese

Description based upon print version of record.

Includes bibliographical references (p. [297]-314) and index.

Introduction to Cluster Dynamics; Preface; Contents; 1 About clusters; 1.1 Atoms,molecules andsolids; 1.1.1 Atoms; 1.1.2 Molecules; 1.1.3 The point of view of solid state physics; 1.2 Clusters between atom and bulk; 1.2.1 Clusters as scalable finite objects; 1.2.2 Varying cluster material; 1.3 Metal clusters; 1.3.1 Some specific properties; 1.3.2 Ontime scales; 1.3.3 Optical properties; 1.4 Conclusion; 2 From clusters to numbers: experimental aspects; 2.1 Production of clusters; 2.1.1 Cluster production in supersonic jets: a telling example; 2.1.2 More cluster sources

2.1.3 Which clusters for which physics2.2 Basic experimental tools; 2.2.1 Mass spectrometers; 2.2.2 Optical spectroscopy; 2.2.3 Photoelectron spectroscopy; 2.3 Examples of measurements; 2.3.1 Abundances; 2.3.2 Ionization potentials; 2.3.3 Static polarizabilities; 2.3.4 Optical response; 2.3.5 Vibrational spectra; 2.3.6 Conductivity; 2.3.7 Magnetic moments; 2.3.8 Photoelectron spectroscopy; 2.3.9 Heat capacity; 2.3.10 Dissociation energies; 2.3.11 Limit of stability; 2.3.12 Femtosecond spectroscopy; 2.4 Conclusion; 3 The cluster many-body problem: a theoretical perspective

3.1 Ions andelectrons3.1.1 An example of true cluster dynamics; 3.1.2 The full many-body problem; 3.1.3 Approximations for the ions as such; 3.2 Approximation chain for the ion-electron coupling; 3.2.1 Core andvalence electrons; 3.2.2 Pseudo-potentials; 3.2.3 Jellium approach to the ionic background; 3.3 Approximation chainfor electrons; 3.3.1 Exact calculations; 3.3.2 Ab initio approaches; 3.3.3 Density-functional theory; 3.3.4 Phenomenological electronic shell models; 3.3.5 Semiclassical approaches; 3.4 Putting things together; 3.4.1 Coupled ionic and electronic dynamics

3.4.2 Born-OppenheimerMD3.4.3 Structure optimization; 3.4.4 Modeling interfaces; 3.4.5 Approaches eliminating the electrons; 3.5 Conclusions; 4 Gross properties and trends; 4.1 Observables; 4.1.1 Excitationmechanisms; 4.1.2 Energies; 4.1.3 Shapes; 4.1.4 Emission; 4.1.5 Polarizability; 4.1.6 Conductivity; 4.1.7 Spectral analysis; 4.2 Structure; 4.2.1 Shells; 4.2.2 Shapes; 4.3 Optical response; 4.3.1 Mie plasmon, basic trends; 4.3.2 Basic features of the plasmon resonance; 4.3.3 Effectsof deformation; 4.3.4 Othermaterials; 4.3.5 Widths; 4.4 Metal clusters andnuclei; 4.4.1 Bulkproperties

4.4.2 Shell effects4.4.3 Collective response; 4.4.4 Fission; 4.4.5 Clusterversusnuclear time scales; 4.5 Conclusions; 5 New frontiers in cluster dynamics; 5.1 Structure; 5.1.1 Fractal growth; 5.1.2 Hedroplets; 5.1.3 Heat capacity; 5.1.4 Static polarizability; 5.1.5 Magnetic properties; 5.2 Observables from linear response; 5.2.1 Optical absorption; 5.2.2 Beyond dipole modes; 5.2.3 Photoelectron spectroscopy; 5.3 Laser excitations in the semi-linear regime; 5.3.1 Electron emission; 5.3.2 Shaping clusters; 5.3.3 Ionic effects in laser pulses of varied length; 5.3.4 Pump andprobe analysis

5.4 Excitation byparticle impact

Clusters as mesoscopic particles represent an intermediate state of matter between single atoms and solid material. The tendency to miniaturise technical objects requires knowledge about systems which contain a ""small"" number of atoms or molecules only. This is all the more true for dynamical aspects, particularly in relation to the qick development of laser technology and femtosecond spectroscopy. Here, for the first time is a highly qualitative introduction to cluster physics. With its emphasis on cluster dynamics, this will be vital to everyone involved in this interdisciplinary subje