Physical Review Research (Sep 2020)

Interfacial-hybridization-modified Ir ferromagnetism and electronic structure in LaMnO_{3}/SrIrO_{3} superlattices

  • Yujun Zhang,
  • Yong Zheng Luo,
  • Liang Wu,
  • Motohiro Suzuki,
  • Qinghua Zhang,
  • Yasuyuki Hirata,
  • Kohei Yamagami,
  • Kou Takubo,
  • Keisuke Ikeda,
  • Kohei Yamamoto,
  • Akira Yasui,
  • Naomi Kawamura,
  • Chun Lin,
  • Keisuke Koshiishi,
  • Xin Liu,
  • Jinxing Zhang,
  • Yasushi Hotta,
  • X. Renshaw Wang,
  • Atsushi Fujimori,
  • Yuanhua Lin,
  • Cewen Nan,
  • Lei Shen,
  • Hiroki Wadati

DOI
https://doi.org/10.1103/PhysRevResearch.2.033496
Journal volume & issue
Vol. 2, no. 3
p. 033496

Abstract

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Artificially fabricated 3d/5d superlattices (SLs) involve both strong electron correlation and spin-orbit coupling in one material by means of interfacial 3d-5d coupling, whose mechanism remains mostly unexplored. In this work we investigated the mechanism of interfacial coupling in LaMnO_{3}/SrIrO_{3} SLs by several spectroscopic approaches. Hard x-ray absorption, magnetic circular dichroism and photoemission spectra evidence the systematic modulation of the Ir ferromagnetism and the electronic structure with the change of the SL repetition period. First-principles calculations further reveal the mechanism of the SL-period dependence of the interfacial electronic structure and the local properties of the Ir moments, confirming that the formation of Ir-Mn molecular orbital is responsible for the interfacial coupling effects. The SL-period dependence of the ratio between orbital and spin components of the Ir magnetic moments can be attributed to the realignment of electron spin during the formation of the interfacial molecular orbital. Our results clarify the nature of interfacial coupling in this prototypical 3d/5d SL system and the conclusion will shed light on the study of other strongly correlated and spin-orbit coupled oxide heterointerfaces.