The Superconducting Gap Behavior in the Antiferromagnetic Nickel-Borocarbide Compounds RNi2B2C (R=Dy, Ho, Er, Tm) Studied by Point-Contacts Spectroscopy

TL;DR

This study investigates the superconducting gap behavior in RNi2B2C compounds with magnetic rare-earth ions using point-contact spectroscopy, revealing multiband features and magnetic order effects on the superconducting properties.

Contribution

It provides the first detailed analysis of how antiferromagnetic order influences the superconducting gap in these nickel-borocarbide compounds, incorporating pair-breaking effects and multiband considerations.

Findings

Evidence for two superconducting gaps in Er-compound

Decrease of gaps in the antiferromagnetic state for R=Er and Tm

BCS-like gap behavior in Dy and Ho compounds

Abstract

An general survey of the superconducting (SC) gap study in the title compounds by point-contact (PC) spectroscopy is presented. The SC gap was determined from dV/dI of PCs employing the well-known theory of conductivity for normal metal-superconductor PCs accounting Andreev reflection. The theory was modified by including pair-breaking effects considering the presence of magnetic rare-earth ions. A possible multiband structure of these compounds was also taken into account. The PC study of the gap in the Er-compound (TN=6K<Tc=11K) gives =evidence for the presence of two SC gaps. Additionally, a distinct decrease of both gaps is revealed for R = Er in the antiferromagnetic (AF) state. For R = Tm (TN=1.5K<Tc=10.5K) a decrease of the SC gap is observed below 4-5K, while for R = Dy (TN=10.5K>Tc=6.5K) the SC gap has a BCS-like dependence in the AF state. The SC gap for R = Ho (TN=5.2K<Tc=8.5K) exhibits below T*=5.6K a single-band BCS-like dependence vanishing above T*, where a specific magnetic order occurs. The difference in the SC gap behavior in the title compounds is attributed to different AF ordering.