SPECKLE FROM PHASE-ORDERING SYSTEMS

The statistical properties of coherent radiation scattered from phase- ordering materials are studied in detail using large-scale computer si mulations and analytic arguments. Specifically, we consider a two-dime nsional model with a nonconserved, scalar order parameter (model A), q uenched through an order-disorder transition into the two-phase regime . For such systems it is well established that the standard scaling hy pothesis applies, consequently, the average scattering intensity at wa ve vector k and time tau is proportional to a scaling function which d epends only on a rescaled time, t similar to \k\(2) tau. We find that the simulated intensities are exponentially distributed, and the time- dependent average is well approximated using a scaling function due to Ohta, Jasnow, and Kawasaki. Considering fluctuations around the avera ge behavior, we find that the covariance of the scattering intensity f or a single wave vector at two different times is proportional to a sc aling function with natural variables delta t = \t(1) - t(2)\ and (t) over bar = (t(1) + t(2))/2. In the asymptotic large-(t) over bar limit this scaling function depends only on z = delta t/(t) over bar(1/2). For small values of z, the scaling function is quadratic, correspondin g to highly persistent behavior of the intensity fluctuations. We empi rically establish that the intensity covariance (for k not equal 0) eq uals the square of the spatial Fourier transform of the two-time, two- point correlation function of the order parameter. This connection all ows sensitive testing, either experimental or numerical, of existing t heories for two-time correlations in systems undergoing order-disorder phase transitions. Comparison between theoretical scaling functions a nd our numerical results requires no adjustable parameters.