English

Underscreened Kondo Compensation in a Superconductor

Mesoscale and Nanoscale Physics 2025-09-29 v1 Superconductivity

Abstract

A magnetic impurity with a larger S=1S=1 spin remains partially screened by the Kondo effect when embedded in a metal. However, when placed within an ss-wave superconductor, the interplay between the superconducting energy gap Δ\Delta and the Kondo temperature TKT_K induces a quantum phase transition from an underscreened doublet Kondo to an unscreened triplet phase, typically occurring when Δ/TK1\Delta/T_K\approx 1. We investigate the Kondo compensation of the impurity spin resulting from this partial screening across the quantum phase transition, which together with the spin-spin correlation function serves as a measure of the Kondo cloud's integrity. Deep within the unscreened triplet phase, Δ/TK1\Delta/T_K\gg 1, the compensation vanishes, signifying complete decoupling of the impurity spin from the environment, while in the partially screened doublet phase, Δ/TK1\Delta/T_K\ll 1, it asymptotically approaches 1/21/2, indicating that half of the spin is screened. Notably, there is a universal jump in the compensation precisely at the phase transition, which we accurately calculate. The spin-spin correlation function exhibits an oscillatory pattern with an envelope function decaying as 1/x\sim 1/x at short distances. At larger distances, the superconducting gap induces an exponentially decaying behavior exp(x/ξΔ)\sim \exp(-x/\xi_\Delta) governed by the superconducting correlation length ξΔ\xi_\Delta, irrespective of the phase, without any distinctive features across the transition. Furthermore, the spectral functions of some relevant operators are evaluated and discussed. In terms of the methods used, a consistent description is provided through the application of multiplicative, numerical and density matrix renormalization group techniques.

Keywords

Cite

@article{arxiv.2412.13687,
  title  = {Underscreened Kondo Compensation in a Superconductor},
  author = {Anand Manaparambil and Cătălin Paşcu Moca and Gergely Zaránd and Ireneusz Weymann},
  journal= {arXiv preprint arXiv:2412.13687},
  year   = {2025}
}

Comments

9 pages, 7 figures

R2 v1 2026-06-28T20:40:13.181Z