Anomalous Nernst Effect in the Vortex-Liquid Phase of High-Temperature Superconductors by Layer Decoupling

TL;DR

This paper predicts a linear diamagnetism and anomalous Nernst effect in the vortex-liquid phase of layered high-temperature superconductors, explaining recent experimental observations through a high-temperature XY model analysis.

Contribution

It introduces a theoretical framework linking vortex-liquid phase diamagnetism and Nernst signals to layer decoupling, matching experimental data.

Findings

Diamagnetic susceptibility vanishes as (T_c0 - T)^3 near T_c0

Quantitative agreement with experimental diamagnetic signals

Predicts linear diamagnetism in vortex-liquid phase

Abstract

Linear diamagnetism is predicted in the vortex-liquid phase of layered superconductors at temperatures just below the mean-field phase transition on the basis of a high-temperature analysis of the corresponding frustrated XY model. The diamagnetic susceptibility, and the Nernst signal by implication, is found to vanish with temperature as (T_c0 - T)^3 in the vicinity of the meanfield transition at T_c0. Quantitative agreement with recent experimental observations of a diamagnetic signal in the vortex-liquid phase of high-temperature superconductors is obtained.