Persistence to high temperatures of interlayer coherence in an organic superconductor

TL;DR

This study investigates the persistence of interlayer coherence in an organic superconductor at high temperatures, revealing that coherence remains well above the expected incoherence threshold, with scattering dominated by electron-electron interactions.

Contribution

It demonstrates that interlayer coherence persists at temperatures much higher than the Anderson criterion, using angle-dependent magnetoresistance modeling to analyze quasiparticle paths on a 3D Fermi surface.

Findings

Interlayer coherence persists above the Anderson criterion by a factor of ~30.

The scattering rate shows a T^2 dependence, indicating electron-electron scattering dominance.

The interlayer magnetoresistance peak remains at high temperatures, confirming coherence.

Abstract

The interlayer magnetoresistance $\rho_{zz}$ of the organic metal \cuscn is studied in fields of up to 45 T and at temperatures $T$ from 0.5 K to 30 K. The peak in $\rho_{zz}$ seen in in-plane fields, a definitive signature of interlayer coherence, remains to $T$s exceeding the Anderson criterion for incoherent transport by a factor $\sim 30$. Angle-dependent magnetoresistance oscillations are modeled using an approach based on field-induced quasiparticle paths on a 3D Fermi surface, to yield the $T$ dependence of the scattering rate $\tau^{-1}$. The results suggest that $\tau^{-1}$ does not vary strongly over the Fermi surface, and that it has a $T^2$ dependence due to electron-electron scattering.