Tighter upper bounds on the critical temperature of two-dimensional superconductors and superfluids: Approaching the supremum

Abstract

We discuss standard and tighter upper bounds on the critical temperature Tc of two-dimensional superconductors and superfluids versus particle density n or filling factor , under the assumption that the transition from the normal to the superconducting (superfluid) phase is governed by the Berezinskii-Kosterlitz-Thouless (BKT) mechanism of vortex-antivortex binding and a direct relation between the superfluid density tensor and Tc exists. The standard critical temperature upper bound Tc up1 is obtained from the Glover-Ferrell-Tinkham sum rule for the optical conductivity, which constrains the superfluid density tensor components. However, we show that Tc up1 is only useful in the limit of low particle/carrier density, where it may be close to the critical temperature supremum Tc sup . For intermediate and high particle/carrier densities, Tc up1 is far beyond Tc sup for any given interaction strength. We demonstrate that it is imperative to consider at least the full effects of phase fluctuations of the order parameter for superconductivity (superfluidity) to establish tighter bounds over a wide range of densities. Using the renormalization group, we obtain the critical temperature supremum for phase fluctuations Tc and show that it is a much tighter upper bound to Tc sup than Tc up1 for all particle/carrier densities. We conclude by indicating that if the Tc is exceeded in experiments involving single band systems, then a non-BKT mechanism must be invoked.