Quantum Monte Carlo study of a magnetic-field-driven 2D superconductor-insulator transition

Abstract

We numerically study the superconductor-insulator phase transition in a model disordered 2D superconductor as a function of applied magnetic field. The calculation involves quantum Monte Carlo calculations of the (2+1)D XY model in the presence of both disorder and magnetic field. The XY coupling is assumed to have the form -J(θi-θj-Aij), where Aij has a mean of zero and a standard deviation Aij. In a real system, such a model would be approximately realized by a 2D array of small Josephson-coupled grains with slight spatial disorder and a uniform applied magnetic field. The different values Aij then corresponds to an applied field such that the average number of flux quanta per plaquette has various integer values N: larger N corresponds to larger Aij. For any value of Aij, there appears to be a critical coupling constant Kc( Aij)=[J/(2U)]c, where U is the charging energy, above which the system is a Mott insulator; there is also a corresponding critical conductivity σ*( Aij) at the transition. For Aij=∞, the order parameter of the transition is a renormalized coupling constant g. Using a numerical technique appropriate for disordered systems, we show that the transition at this value of Aij takes place from an insulating (I) phase to a Bose glass (BG) phase, and that the dynamical critical exponent characterizing this transition is z 1.3. By contrast, z=1 for this model at Aij=0. We suggest that the superconductor to insulator transition is actually of this I to BG class at all nonzero Aij's, and we support this interpretation by both numerical evidence and an analytical argument based on the Harris criterion.