Temporal Evolution of Step-Edge Fluctuations Under Electromigration Conditions

Abstract

The temporal evolution of step-edge fluctuations under electromigration conditions is analysed using a continuum Langevin model. If the electromigration driving force acts in the step up/down direction, and step-edge diffusion is the dominant mass-transport mechanism, we find that significant deviations from the usual t1/4 scaling of the terrace-width correlation function occurs for a critical time τ which is dependent upon the three energy scales in the problem: kBT, the step stiffness, γ, and the bias associated with adatom hopping under the influence of an electromigration force, U. For (t < τ), the correlation function evolves as a superposition of t1/4 and t3/4 power laws. For t τ a closed form expression can be derived. This behavior is confirmed by a Monte-Carlo simulation using a discrete model of the step dynamics. It is proposed that the magnitude of the electromigration force acting upon an atom at a step-edge can by estimated by a careful analysis of the statistical properties of step-edge fluctuations on the appropriate time-scale.