• Produktbild: Spatio-Temporal Pattern Formation
  • Produktbild: Spatio-Temporal Pattern Formation

Spatio-Temporal Pattern Formation With Examples from Physics, Chemistry, and Materials Science

Fr. 72.90

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Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

27.09.2012

Verlag

Springer Us

Seitenzahl

306

Maße (L/B/H)

23.5/15.5/1.8 cm

Gewicht

487 g

Auflage

Softcover reprint of the original 1st ed. 1997

Sprache

Englisch

ISBN

978-1-4612-7311-0

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

27.09.2012

Verlag

Springer Us

Seitenzahl

306

Maße (L/B/H)

23.5/15.5/1.8 cm

Gewicht

487 g

Auflage

Softcover reprint of the original 1st ed. 1997

Sprache

Englisch

ISBN

978-1-4612-7311-0

Herstelleradresse

Springer-Verlag KG
Sachsenplatz 4-6
1201 Wien
AT

Email: GPSR Kontakt

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  • Produktbild: Spatio-Temporal Pattern Formation
  • Produktbild: Spatio-Temporal Pattern Formation
  • 1 Introduction.- 2 Instabilities and Patterns in Hydrodynamical Systems.- 2.1 Rayleigh-Bénard instability.- 2.2 Taylor-Couette instability.- 2.3 Liquid crystal instabilities.- 3 Instabilities and Patterns in Reaction-Diffusion Systems.- 3.1 Chemical instabilities.- 3.2 Defect microstructures in irradiated materials.- 3.3 Plastic deformation and dislocation patterns.- 4 Generic Aspects of Pattern-Forming Instabilities.- 4.1 Phenomenology.- 4.2 Reaction-diffusion dynamics and stability.- 4.3 Reduced dynamics and amplitude equations.- 4.4 Spatial patterns: selection and stability.- 4.4.1 Isotropic systems.- 4.4.2 Anisotropic systems.- 4.5 Phase dynamics of periodic patterns.- 4.5.1 Isotropic systems.- 4.5.2 Anisotropic systems.- 5 The Hopf Bifurcation and Related Spatio-Temporal Patterns.- 5.1 The generic aspects of oscillatory media.- 5.1.1 The complex Ginzburg-Landau equation.- 5.1.2 Phase dynamics and spiral waves.- 5.2 Real chemical systems and the complex Ginzburg-Landau equation.- 5.2.1 Determination of the CGLE parameters in real systems.- 5.2.2 CGLE parameters of the BZ reaction.- 5.3 The effect of natural forcings on chemical oscillators.- 5.3.1 The effect of convection on chemical waves.- 5.3.2 The effect of vertical gradients on chemical oscillations.- 5.4 Conclusions.- 6 The Turing Instability and Associated Spatial Structures.- 6.1 The Turing mechanism.- 6.2 The search for Turing structures.- 6.2.1 Convectively driven chemical patterns.- 6.2.2 Double diffusion and chemical fingers.- 6.3 At last, genuine Turing structures?.- 6.4 The interaction between Turing and Hopf instabilities.- 6.4.1 Amplitude equations for Turing-Hopf modes.- 6.4.2 Pattern selection for codimension-2 Turing-Hopf bifurcations.- 6.4.3 Defects, defect bifurcations and localized structures.- 7 Defects and Defect Bifurcations.- 7.1 Generic existence of defects.- 7.2 Examples of defects.- 7.2.1 Codimension-1 defects.- 7.2.2 Codimension-2 defects.- 7.3 Defects and disorder.- 7.4 Bifurcation of defects.- 8 The Effect of External Fields.- 8.1 Spatial forcing of stationary patterns.- 8.1.1 Resonant forcings.- 8.1.2 Near-resonant forcings and commensurate incommensurate transitions.- 8.2 Temporal forcing of a Hopf bifurcation.- 8.3 Temporal forcing of one-dimensional wave patterns.- 8.3.1 Pattern selection and defects.- 8.3.2 Experimental observations.- 8.4 Temporal forcing of two-dimensional wave patterns.- 8.4.1 Isotropic systems.- 8.4.2 Anisotropic systems.- 8.5 Spatial forcing of wave patterns.- 8.6 Flow field effects on pattern forming instabilities.- 8.7 The effect of noise on wave patterns.- 8.8 Conclusions.- 9 Fronts.- 9.1 One-dimensional aspects.- 9.1.1 The leading-edge approach.- 9.1.2 Breakdown of the leading-edge approach.- 9.1.3 Envelope fronts.- 9.1.4 Multiple fronts.- 9.2 Two-dimensional aspects.- 9.2.1 Propagation of roll patterns.- 9.2.2 Propagation of hexagonal patterns.- 10 Pattern Formation: Generic versus Nongeneric Aspects.- 10.1 Kinetic coefficients.- 10.2 Nongradient dynamics.- 10.3 Experimental set-ups.- 11 Microstructures in Irradiated Materials.- 11.1 Particle irradiation of metals and alloys.- 11.1.1 A rate theory model for microstructure evolution under irradiation.- 11.1.2 Dislocation loop dynamics.- 11.1.3 The linear stability analysis.- 11.1.4 The weakly nonlinear regime.- 11.1.5 Numerical analysis.- 11.1.6 Conclusions.- 11.2 Laser induced deformation of surfaces.- 11.2.1 Thin film dynamics under laser irradiation.- 11.2.2 Linear stability analysis.- 11.2.3 Weakly nonlinear analysis.- 11.2.4 Finite size effects.- 11.2.5 Conclusions.- 12 Plastic Instabilities.- 12.1 Dislocation dynamics and rate equations.- 12.2 Stability analysis and bifurcations.- 12.3 Nonlinear analysis.- 12.4 Multiple slip.- 13 Afterword.- 14 Appendices.- 14.1 Bifurcations and normal forms.- 14.1.1 Bifurcations.- 14.1.2 Stability of equilibria.- 14.1.3 Lyapounov functions.- 14.1.4 Typical bifurcation examples.- 14.1.5 The Hopf bifurcation theorem.- 14.1.6 The Center Manifold Theorem.- 14.2 More about dynamical models.- 14.2.1 Proctor-Sivashinsky.- 14.2.2 Ginzburg-Landau.- 14.3 The Brusselator: A toy model for pattern formation in RD systems.- 14.3.1 The Turing instability.- 14.3.2 The Hopf Instability.- 14.3.3 Amplitude equations for Turing-Hopf modes.- 14.4 Resonant forcings of nonlinear oscillators.- 14.4.1 Parametric forcing.- 14.4.2 Strong resonances in spatially extended systems.- 14.4.3 Stationary solutions and resonance horns.- 14.4.4 From oscillations to excitability.