Apparent double-Tc from a single BKT transition in anisotropic phase-only models

Abstract

Transport experiments on two-dimensional superconductors often yield direction-dependent transition temperatures, raising the question of whether such a ``double-Tc'' reflects a true thermodynamic splitting or a transport artifact. To establish a baseline, we study a minimal anisotropic phase-only Josephson-junction array in equilibrium and under resistively shunted junction dynamics with fluctuating twist boundary conditions. The equilibrium model exhibits a single Berezinskii--Kosterlitz--Thouless (BKT) transition. Out of equilibrium, anisotropic Josephson couplings and anisotropic dissipation reshape the linear R--T curves in a finite-size, finite-current crossover regime, so that curve-shape criteria such as Halperin--Nelson fits and fixed-resistance thresholds yield an apparent double-Tc. In contrast, critical-scaling criteria -- the universal exponent α=3 and dynamic finite-size scaling -- remain consistent with the single TBKT. A robust splitting that persists in the nonlinear critical scaling, such as that recently reported at KTaO3 interfaces, therefore points to physics beyond this clean anisotropic baseline.