Kibble Zurek mechanism in rapidly quenched phase transition dynamics
Abstract
We propose a theory to explain the experimental observed deviation from the Kibble-Zurek mechanism (KZM) scaling in rapidly quenched critical phase transition dynamics. There is a critical quench rate τQc1 above it the KZM scaling begins to appear. Smaller than τQc1, the defect density n is a constant independent of the quench rate but depends on the final temperature Tf as n Ld εTf d , the freeze out time t admits the scaling law t εTf- z where d is the spatial dimension, εTf= (1-Tf/Tc) is the dimensionless reduced temperature, L is the sample size, and z are spatial and dynamical critical exponents. Quench from Tc, the critical rate is determined by the final temperature Tf as τQc1 εTf-(1+z ) . All the scaling laws are verified in a rapidly quenched superconducting ring via the AdS/CFT correspondence.
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