Parity Effect in Ground State Energies of Ultrasmall Superconducting Grains

TL;DR

This paper investigates how the ground state energy of ultrasmall superconducting grains varies with electron number parity and grain size, revealing a crossover from superconducting to normal state as level spacing increases.

Contribution

It introduces a detailed analysis of the parity effect on ground state energies in small superconducting grains, highlighting the non-monotonic behavior of parity-induced energy shifts.

Findings

Parity-dependent energy shifts exhibit non-monotonic dependence on level spacing.

Crossover from superconducting to normal state occurs as level spacing increases.

Predictions can be tested via Coulomb blockade peak measurements in different-sized grains.

Abstract

We study the superconductivity in small grains in the regime when the quantum level spacing $\delta\varepsilon$ is comparable to the gap $\Delta$. As $\delta\varepsilon$ is increased, the system crosses over from superconducting to normal state. This crossover is studied by calculating the dependence of the ground state energy of a grain on the parity of the number of electrons. The states with odd numbers of particles carry an additional energy $\Delta_P$, which shows non-monotonic dependence on $\delta\varepsilon$. Our predictions can be tested experimentally by studying the parity-induced alternation of Coulomb blockade peak spacings in grains of different sizes.