Crystal orientation dependent spin pumping in Bi0.1Y2.9Fe5O12/Pt interface

TL;DR

This study investigates how the crystal orientation of epitaxial Bi-YIG thin films affects spin pumping efficiency and spin to charge conversion when interfaced with platinum, revealing significant anisotropy in spin transport properties.

Contribution

It demonstrates the orientation-dependent variation in spin mixing conductance and spin Seebeck coefficient in Bi-YIG/Pt heterostructures, highlighting the role of crystal symmetry in spintronics.

Findings

[111] orientation yields higher spin mixing conductance.

[111] orientation shows increased spin Hall angle.

Higher spin Seebeck coefficient observed in [111] orientation.

Abstract

Ferromagnetic resonance (FMR) based spin pumping is a versatile tool to quantify the spin mixing conductance and spin to charge conversion (S2CC) efficiency of ferromagnet/normal metal (FM/NM) heterostructure. The spin mixing conductance of FM/NM interface can also be tuned by the crystal orientation symmetry of epitaxial FM. In this work, we study the S2CC in epitaxial Bismuth substituted Yttrium Iron Garnet (Bi0.1Y2.9Fe5O12) thin films Bi-YIG (100 nm) interfaced with heavy metal platinum (Pt (8 nm)) deposited by pulsed laser deposition process on different crystal orientation Gd3Ga5O12 (GGG) substrates i.e. [100] and [111]. The crystal structure and surface roughness characterized by X-Ray diffraction and atomic force microscopy measurements establish epitaxial Bi-YIG[100], Bi-YIG[111] orientations and atomically flat surfaces respectively. The S2CC quantification has been realized by two complimentary techniques, (i) FMR-based spin pumping and inverse spin Hall effect (ISHE) at GHz frequency and (ii) temperature dependent spin Seebeck measurements. FMR-ISHE results demonstrate that the [111] oriented Bi-YIG/Pt sample shows significantly higher values of spin mixing conductance ((2.31+-0.23)x10^18 m^-2) and spin Hall angle (0.01+-0.001) as compared to the [100] oriented Bi-YIG/Pt. A longitudinal spin Seebeck measurement reveals that the [111] oriented sample has higher spin Seebeck coefficient (106.40+-10 nV mm-1 K-1). This anisotropic nature of spin mixing conductance and spin Seebeck coefficient in [111] and [100] orientation has been discussed using the magnetic environment elongation along the surface normal or parallel to the growth direction. Our results aid in understanding the role of crystal orientation symmetry in S2CC based spintronics devices.