High-precision Estimate of the Critical Exponents for the Directed Ising Universality Class

Abstract

With extensive Monte Carlo simulations, we present high-precision estimates of the critical exponents of branching annihilating random walks with two offspring, a prototypical model of the directed Ising universality class in one dimension. To estimate the exponents accurately, we propose a systematic method to find corrections to scaling whose leading behavior is supposed to take the form t- in the long-time limit at the critical point. Our study shows that ≈ 0.75 for the number of particles in defect simulations and ≈ 0.5 for other measured quantities, which should be compared with the widely used value of = 1. Using so obtained, we analyze the effective exponents to find that β/\| = 0.2872(2), z = 1.7415(5), η = 0.0000(2), and accordingly, β / = 0.5000(6). Our numerical results for β/\| and z are clearly different from the conjectured rational numbers β/\| = 27 ≈ 0.2857, z = 74= 1.75 by Jensen [Phys. Rev. E, 50, 3623 (1994)]. Our result for β/, however, is consistent with 12, which is believed to be exact.