APL Materials (Oct 2023)

Suppression of spin pumping at metal interfaces

  • Youngmin Lim,
  • Bhuwan Nepal,
  • David A. Smith,
  • Shuang Wu,
  • Abhishek Srivastava,
  • Prabandha Nakarmi,
  • Claudia Mewes,
  • Zijian Jiang,
  • Adbhut Gupta,
  • Dwight D. Viehland,
  • Christoph Klewe,
  • Padraic Shafer,
  • In Jun Park,
  • Timothy Mabe,
  • Vivek P. Amin,
  • Jean J. Heremans,
  • Tim Mewes,
  • Satoru Emori

DOI
https://doi.org/10.1063/5.0156429
Journal volume & issue
Vol. 11, no. 10
pp. 101121 – 101121-13

Abstract

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An electrically conductive metal typically transmits or absorbs a spin current. Here, we report on evidence that interfacing two metal thin films can suppress spin transmission and absorption. We examine spin pumping in spin-source/spacer/spin-sink heterostructures, where the spacer consists of metallic Cu and Cr thin films. The Cu/Cr spacer largely suppresses spin pumping—i.e., neither transmitting nor absorbing a significant amount of spin current—even though Cu or Cr alone transmits a sizable spin current. The antiferromagnetism of Cr is not essential for the suppression of spin pumping, as we observe similar suppression with Cu/V spacers with V as a nonmagnetic analog of Cr. We speculate that diverse combinations of spin-transparent metals may form interfaces that suppress spin pumping, although the underlying mechanism remains unclear. Our work may stimulate a new perspective on spin transport in metallic multilayers.