Universal crossover in surface superconductivity: Impact of varying Debye energy

Abstract

Recently, interference-induced surface superconductivity (SC) has been predicted within an attractive Hubbard model with s-wave pairing, prompting intensive studies of its properties. The most notable finding is that the surface critical temperature Tcs can be significantly enhanced relative to the bulk critical temperature Tcb. In this work, considering a 1D attractive Hubbard model for the half-filling level, we investigate how this enhancement is affected by variations in the Debye energy ωD, which controls the number of states contributing to the pair potential and, in turn, influences the critical temperature. Our study reveals a universal crossover of the surface SC from the weak- to strong-coupling regime, regardless of the specific value of the Debye energy. The location of this crossover is marked by the maximum of τ = (Tcs - Tcb)/Tcb, which depends strongly on ωD. At its maximum, τ can increase up to nearly 70\%. Additionally, we examine the evolution of the ratio s0/kB Tcs along the crossover, where s0 is the zero-temperature pair potential near the surface (the chain ends), and demonstrate that this ratio can significantly deviate from b0/kB Tcb, where b0 is the zero-temperature bulk pair potential (in the chain center). Our findings may offer valuable insights into the search for higher critical temperatures in narrow-band superconductors.

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