Enhanced Spin-Orbit Coupling in Heavy Metals via Molecular Coupling

Satam Alotibi; Bryan J. Hickey; Gilberto Teobaldi; Mannan Ali; Joseph Barker; Emiliano Poli; David D. O'Regan; Quentin Ramasse; Gavin Burnell; James Patchett; Chiara Ciccarelli; Mohammed Alyami; Timothy Moorsom; Oscar Cespedes

doi:10.1021/acsami.0c19403

Enhanced Spin-Orbit Coupling in Heavy Metals via Molecular Coupling

Satam Alotibi, Bryan J. Hickey, Gilberto Teobaldi, Mannan Ali, Joseph Barker, Emiliano Poli, David D. O'Regan, Quentin Ramasse, Gavin Burnell, James Patchett, Chiara Ciccarelli, Mohammed Alyami, Timothy Moorsom, Oscar Cespedes

Research output: Contribution to journal › Article › peer-review

12 Scopus citations

Abstract

5d metals are used in electronics because of their high spin-orbit coupling (SOC) leading to efficient spin-electric conversion. When C60 is grown on a metal, the electronic structure is altered due to hybridization and charge transfer. In this work, we measure the spin Hall magnetoresistance for Pt/C60 and Ta/C60, finding that they are up to a factor of 6 higher than those for pristine metals, indicating a 20-60% increase in the spin Hall angle. At low fields of 1-30 mT, the presence of C60 increased the anisotropic magnetoresistance by up to 700%. Our measurements are supported by noncollinear density functional theory calculations, which predict a significant SOC enhancement by C60 that penetrates through the Pt layer, concomitant with trends in the magnetic moment of transport electrons acquired via SOC and symmetry breaking. The charge transfer and hybridization between the metal and C60 can be controlled by gating, so our results indicate the possibility of dynamically modifying the SOC of thin metals using molecular layers. This could be exploited in spin-transfer torque memories and pure spin current circuits.

Original language	English
Pages (from-to)	5228-5234
Number of pages	7
Journal	ACS Applied Materials and Interfaces
Volume	13
Issue number	4
DOIs	https://doi.org/10.1021/acsami.0c19403
State	Published - 3 Feb 2021
Externally published	Yes

Keywords

charge transfer
emergent functionalities
metallo-molecular interfaces
molecular spintronics
spin hall angle
spin-orbit interaction
yttrium iron garnet

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10.1021/acsami.0c19403

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title = "Enhanced Spin-Orbit Coupling in Heavy Metals via Molecular Coupling",

abstract = "5d metals are used in electronics because of their high spin-orbit coupling (SOC) leading to efficient spin-electric conversion. When C60 is grown on a metal, the electronic structure is altered due to hybridization and charge transfer. In this work, we measure the spin Hall magnetoresistance for Pt/C60 and Ta/C60, finding that they are up to a factor of 6 higher than those for pristine metals, indicating a 20-60\% increase in the spin Hall angle. At low fields of 1-30 mT, the presence of C60 increased the anisotropic magnetoresistance by up to 700\%. Our measurements are supported by noncollinear density functional theory calculations, which predict a significant SOC enhancement by C60 that penetrates through the Pt layer, concomitant with trends in the magnetic moment of transport electrons acquired via SOC and symmetry breaking. The charge transfer and hybridization between the metal and C60 can be controlled by gating, so our results indicate the possibility of dynamically modifying the SOC of thin metals using molecular layers. This could be exploited in spin-transfer torque memories and pure spin current circuits.",

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T1 - Enhanced Spin-Orbit Coupling in Heavy Metals via Molecular Coupling

AU - Alotibi, Satam

AU - Hickey, Bryan J.

AU - Teobaldi, Gilberto

AU - Ali, Mannan

AU - Barker, Joseph

AU - Poli, Emiliano

AU - O'Regan, David D.

AU - Ramasse, Quentin

AU - Burnell, Gavin

AU - Patchett, James

AU - Ciccarelli, Chiara

AU - Alyami, Mohammed

AU - Moorsom, Timothy

AU - Cespedes, Oscar

N1 - Publisher Copyright: ©

PY - 2021/2/3

Y1 - 2021/2/3

N2 - 5d metals are used in electronics because of their high spin-orbit coupling (SOC) leading to efficient spin-electric conversion. When C60 is grown on a metal, the electronic structure is altered due to hybridization and charge transfer. In this work, we measure the spin Hall magnetoresistance for Pt/C60 and Ta/C60, finding that they are up to a factor of 6 higher than those for pristine metals, indicating a 20-60% increase in the spin Hall angle. At low fields of 1-30 mT, the presence of C60 increased the anisotropic magnetoresistance by up to 700%. Our measurements are supported by noncollinear density functional theory calculations, which predict a significant SOC enhancement by C60 that penetrates through the Pt layer, concomitant with trends in the magnetic moment of transport electrons acquired via SOC and symmetry breaking. The charge transfer and hybridization between the metal and C60 can be controlled by gating, so our results indicate the possibility of dynamically modifying the SOC of thin metals using molecular layers. This could be exploited in spin-transfer torque memories and pure spin current circuits.

AB - 5d metals are used in electronics because of their high spin-orbit coupling (SOC) leading to efficient spin-electric conversion. When C60 is grown on a metal, the electronic structure is altered due to hybridization and charge transfer. In this work, we measure the spin Hall magnetoresistance for Pt/C60 and Ta/C60, finding that they are up to a factor of 6 higher than those for pristine metals, indicating a 20-60% increase in the spin Hall angle. At low fields of 1-30 mT, the presence of C60 increased the anisotropic magnetoresistance by up to 700%. Our measurements are supported by noncollinear density functional theory calculations, which predict a significant SOC enhancement by C60 that penetrates through the Pt layer, concomitant with trends in the magnetic moment of transport electrons acquired via SOC and symmetry breaking. The charge transfer and hybridization between the metal and C60 can be controlled by gating, so our results indicate the possibility of dynamically modifying the SOC of thin metals using molecular layers. This could be exploited in spin-transfer torque memories and pure spin current circuits.

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KW - emergent functionalities

KW - metallo-molecular interfaces

KW - molecular spintronics

KW - spin hall angle

KW - spin-orbit interaction

KW - yttrium iron garnet

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Enhanced Spin-Orbit Coupling in Heavy Metals via Molecular Coupling

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