Depinning transition of charge-density waves: mapping onto O(n) symmetric φ4 theory with n -2 and loop-erased random walks

Abstract

Driven periodic elastic systems such as charge-density waves (CDWs) pinned by impurities show a non-trivial, glassy dynamical critical behavior. Their proper theoretical description requires the functional renormalization group. We show that their critical behavior close to the depinning transition is related to a much simpler model, O(n)-symmetric φ4 theory in the unusual limit of n -2. We demonstrate that both theories yield identical results to 4-loop order and give both a perturbative and a non-perturbative proof of their equivalence. As we show, both theories can be used to describe loop-erased random walks (LERWs), the trace of a random walk where loops are erased as soon as they are formed. Remarkably, two famous models of non-self-intersecting random walks, self-avoiding walks (SAWs) and LERWs, can both be mapped onto φ4 theory taken, with formally n=0 and n -2 components. This mapping allows us to compute the dynamic critical exponent of CDWs at the depinning transition and the fractal dimension of LERWs in d=3 with unprecedented accuracy, z(d=3)= 1.6243 0.001, in excellent agreement with the estimate z = 1.624 00 0.00005 of numerical simulations.