Voltage- And temperature-dependent rare-earth dopant contribution to the interfacial magnetic anisotropy

Alejandro O. Leon; Gerrit E.W. Bauer

doi:10.1088/1361-648X/ab997c

Voltage- And temperature-dependent rare-earth dopant contribution to the interfacial magnetic anisotropy

Alejandro O. Leon, Gerrit E.W. Bauer

Advanced Institute for Materials Research (AIMR)

Universidad Tecnológica Metropolitana

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

2 Citations (Scopus)

Abstract

The control of magnetic materials and devices by voltages without electric currents holds the promise of power-saving nano-scale devices. Here we study the temperature-dependent voltage control of the magnetic anisotropy caused by rare-earth (RE) local moments at an interface between a magnetic metal and a non-magnetic insulator, such as Co|(RE)|MgO. Based on a Stevens operator representation of crystal and applied field effects, we find large dominantly quadrupolar intrinsic and field-induced interface anisotropies at room temperature. We suggest improved functionalities of transition metal tunnel junctions by dusting their interfaces with rare earths.

Original language	English
Article number	404004
Journal	Journal of Physics Condensed Matter
Volume	32
Issue number	40
DOIs	https://doi.org/10.1088/1361-648X/ab997c
Publication status	Published - 2020 Sept 23

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10.1088/1361-648X/ab997c

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title = "Voltage- And temperature-dependent rare-earth dopant contribution to the interfacial magnetic anisotropy",

abstract = "The control of magnetic materials and devices by voltages without electric currents holds the promise of power-saving nano-scale devices. Here we study the temperature-dependent voltage control of the magnetic anisotropy caused by rare-earth (RE) local moments at an interface between a magnetic metal and a non-magnetic insulator, such as Co|(RE)|MgO. Based on a Stevens operator representation of crystal and applied field effects, we find large dominantly quadrupolar intrinsic and field-induced interface anisotropies at room temperature. We suggest improved functionalities of transition metal tunnel junctions by dusting their interfaces with rare earths.",

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AU - Leon, Alejandro O.

AU - Bauer, Gerrit E.W.

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PY - 2020/9/23

Y1 - 2020/9/23

N2 - The control of magnetic materials and devices by voltages without electric currents holds the promise of power-saving nano-scale devices. Here we study the temperature-dependent voltage control of the magnetic anisotropy caused by rare-earth (RE) local moments at an interface between a magnetic metal and a non-magnetic insulator, such as Co|(RE)|MgO. Based on a Stevens operator representation of crystal and applied field effects, we find large dominantly quadrupolar intrinsic and field-induced interface anisotropies at room temperature. We suggest improved functionalities of transition metal tunnel junctions by dusting their interfaces with rare earths.

AB - The control of magnetic materials and devices by voltages without electric currents holds the promise of power-saving nano-scale devices. Here we study the temperature-dependent voltage control of the magnetic anisotropy caused by rare-earth (RE) local moments at an interface between a magnetic metal and a non-magnetic insulator, such as Co|(RE)|MgO. Based on a Stevens operator representation of crystal and applied field effects, we find large dominantly quadrupolar intrinsic and field-induced interface anisotropies at room temperature. We suggest improved functionalities of transition metal tunnel junctions by dusting their interfaces with rare earths.

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Voltage- And temperature-dependent rare-earth dopant contribution to the interfacial magnetic anisotropy

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