W.C. Tang, H. Rosen, et al.
SPIE Optics, Electro-Optics, and Laser Applications in Science and Engineering 1991
In the complex Ginzburg-Landau equation, we consider possible "phase turbulent" regimes, where asymptotic correlations are controlled by phase fluctuations rather than by topological defects. Conjecturing that the decay of such correlations is governed by the Kardar-Parisi-Zhang (KPZ) model of growing interfaces, we derive the following results: (1) A scaling ansatz implies that equal-time spatial correlations in 1d, 2d, and 3d decay like e-Ax2ζ̃, where A is a nonuniversal constant, and ζ = 1/2 in 1d. (2) Temporal correlations decay as exp(-t2β̃h(t/ Lz)), with the scaling law β̃ = ζ̃/z, where z = 3/2, 1.58 . . . , and 1.66 . . . , for d = 1,2, and 3 respectively. The scaling function h(y) approaches a constant as y→0, and behaves like y2(β̂-β̃) for large y. If in 3d the associated KPZ model turns out to be in its weak-coupling ("smooth") phase, then, instead of the above behavior, the CGLE exhibits rotating long-range order whose connected correlations decay like 1/x in space or 1/t1/2 in time. (3) For system sizes, L, and times t respectively less than a crossover length, Lc, and time, tc, correlations are governed by the free-field or Edwards-Wilkinson (EW) equation, rather than the KPZ model. In 1d, we find that Lc is large: Lc ∼ 35,000; for L < Lc we show numerical evidence for stretched exponential decay of temporal correlations with an exponent consistent with the EW value βEW = 1/4. © 1996 Elsevier Science B.V. All rights reserved.
W.C. Tang, H. Rosen, et al.
SPIE Optics, Electro-Optics, and Laser Applications in Science and Engineering 1991
Frank R. Libsch, Takatoshi Tsujimura
Active Matrix Liquid Crystal Displays Technology and Applications 1997
Shu Tezuka
WSC 1991
A. Gupta, R. Gross, et al.
SPIE Advances in Semiconductors and Superconductors 1990