Phase transition in the collisionless regime for wave-particle
  interaction

C. Lancellotti; C. Lancellotti; D. F. Escande; G. Manfredi; H. E. Mynick; J. L. Tennyson; J. R. Cary; J. R. Cary; K. Huang; M. Antoni; M. B. Isichenko; M. B. Isichenko; M.-C. Firpo; M.-C. Firpo; Marie-Christine Firpo; P. Stubbe; R. Sugihara; S. H. Strogatz; S. I. Tsunoda; T. M. O'Neil; T. M. O'Neil; V. Latora; Y. Elskens; Y. Elskens; Yves Elskens

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Phase transition in the collisionless regime for wave-particle interaction

Authors: C. Lancellotti
C. Lancellotti
D. F. Escande
G. Manfredi
H. E. Mynick
J. L. Tennyson
J. R. Cary
J. R. Cary
K. Huang
M. Antoni
M. B. Isichenko
M. B. Isichenko
M.-C. Firpo
M.-C. Firpo
Marie-Christine Firpo
P. Stubbe
R. Sugihara
S. H. Strogatz
S. I. Tsunoda
T. M. O'Neil
T. M. O'Neil
V. Latora
Y. Elskens
Y. Elskens
Yves Elskens
Publication date: 21 December 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

Gibbs statistical mechanics is derived for the Hamiltonian system coupling self-consistently a wave to N particles. This identifies Landau damping with a regime where a second order phase transition occurs. For nonequilibrium initial data with warm particles, a critical initial wave intensity is found: above it, thermodynamics predicts a finite wave amplitude in the limit of infinite N; below it, the equilibrium amplitude vanishes. Simulations support these predictions providing new insight on the long-time nonlinear fate of the wave due to Landau damping in plasmas.Comment: 12 pages (RevTeX), 2 figures (PostScript

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