Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices

Diogo C. Vaz; Chia Ching Lin; John J. Plombon; Won Young Choi; Inge Groen; Isabel C. Arango; Andrey Chuvilin; Luis E. Hueso; Dmitri E. Nikonov; Hai Li; Punyashloka Debashis; Scott B. Clendenning; Tanay A. Gosavi; Yen Lin Huang; Bhagwati Prasad; Ramamoorthy Ramesh; Aymeric Vecchiola; Manuel Bibes; Karim Bouzehouane; Stephane Fusil; Vincent Garcia; Ian A. Young; Fèlix Casanova

doi:10.1038/s41467-024-45868-x

Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices

Diogo C. Vaz^*, Chia Ching Lin, John J. Plombon, Won Young Choi, Inge Groen, Isabel C. Arango, Andrey Chuvilin, Luis E. Hueso, Dmitri E. Nikonov, Hai Li, Punyashloka Debashis, Scott B. Clendenning, Tanay A. Gosavi, Yen Lin Huang, Bhagwati Prasad, Ramamoorthy Ramesh, Aymeric Vecchiola, Manuel Bibes, Karim Bouzehouane, Stephane FusilVincent Garcia, Ian A. Young, Fèlix Casanova^*

^*Corresponding author for this work

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

16 Scopus citations

Abstract

As CMOS technologies face challenges in dimensional and voltage scaling, the demand for novel logic devices has never been greater, with spin-based devices offering scaling potential, at the cost of significantly high switching energies. Alternatively, magnetoelectric materials are predicted to enable low-power magnetization control, a solution with limited device-level results. Here, we demonstrate voltage-based magnetization switching and reading in nanodevices at room temperature, enabled by exchange coupling between multiferroic BiFeO₃ and ferromagnetic CoFe, for writing, and spin-to-charge current conversion between CoFe and Pt, for reading. We show that, upon the electrical switching of the BiFeO₃, the magnetization of the CoFe can be reversed, giving rise to different voltage outputs. Through additional microscopy techniques, magnetization reversal is linked with the polarization state and antiferromagnetic cycloid propagation direction in the BiFeO₃. This study constitutes the building block for magnetoelectric spin-orbit logic, opening a new avenue for low-power beyond-CMOS technologies.

Original language	English
Article number	1902
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-024-45868-x
State	Published - Dec 2024

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Vaz, D. C., Lin, C. C., Plombon, J. J., Choi, W. Y., Groen, I., Arango, I. C., Chuvilin, A., Hueso, L. E., Nikonov, D. E., Li, H., Debashis, P., Clendenning, S. B., Gosavi, T. A., Huang, Y. L., Prasad, B., Ramesh, R., Vecchiola, A., Bibes, M., Bouzehouane, K., ... Casanova, F. (2024). Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices. Nature Communications, 15(1), Article 1902. https://doi.org/10.1038/s41467-024-45868-x

@article{1e185f8f8c6641ffb5e7fdf6a0b58174,

title = "Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices",

abstract = "As CMOS technologies face challenges in dimensional and voltage scaling, the demand for novel logic devices has never been greater, with spin-based devices offering scaling potential, at the cost of significantly high switching energies. Alternatively, magnetoelectric materials are predicted to enable low-power magnetization control, a solution with limited device-level results. Here, we demonstrate voltage-based magnetization switching and reading in nanodevices at room temperature, enabled by exchange coupling between multiferroic BiFeO3 and ferromagnetic CoFe, for writing, and spin-to-charge current conversion between CoFe and Pt, for reading. We show that, upon the electrical switching of the BiFeO3, the magnetization of the CoFe can be reversed, giving rise to different voltage outputs. Through additional microscopy techniques, magnetization reversal is linked with the polarization state and antiferromagnetic cycloid propagation direction in the BiFeO3. This study constitutes the building block for magnetoelectric spin-orbit logic, opening a new avenue for low-power beyond-CMOS technologies.",

author = "Vaz, {Diogo C.} and Lin, {Chia Ching} and Plombon, {John J.} and Choi, {Won Young} and Inge Groen and Arango, {Isabel C.} and Andrey Chuvilin and Hueso, {Luis E.} and Nikonov, {Dmitri E.} and Hai Li and Punyashloka Debashis and Clendenning, {Scott B.} and Gosavi, {Tanay A.} and Huang, {Yen Lin} and Bhagwati Prasad and Ramamoorthy Ramesh and Aymeric Vecchiola and Manuel Bibes and Karim Bouzehouane and Stephane Fusil and Vincent Garcia and Young, {Ian A.} and F{\`e}lix Casanova",

note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",

year = "2024",

month = dec,

doi = "10.1038/s41467-024-45868-x",

language = "English",

volume = "15",

journal = "Nature Communications",

issn = "2041-1723",

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Vaz, DC, Lin, CC, Plombon, JJ, Choi, WY, Groen, I, Arango, IC, Chuvilin, A, Hueso, LE, Nikonov, DE, Li, H, Debashis, P, Clendenning, SB, Gosavi, TA, Huang, YL, Prasad, B, Ramesh, R, Vecchiola, A, Bibes, M, Bouzehouane, K, Fusil, S, Garcia, V, Young, IA & Casanova, F 2024, 'Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices', Nature Communications, vol. 15, no. 1, 1902. https://doi.org/10.1038/s41467-024-45868-x

TY - JOUR

T1 - Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices

AU - Vaz, Diogo C.

AU - Lin, Chia Ching

AU - Plombon, John J.

AU - Choi, Won Young

AU - Groen, Inge

AU - Arango, Isabel C.

AU - Chuvilin, Andrey

AU - Hueso, Luis E.

AU - Nikonov, Dmitri E.

AU - Li, Hai

AU - Debashis, Punyashloka

AU - Clendenning, Scott B.

AU - Gosavi, Tanay A.

AU - Huang, Yen Lin

AU - Prasad, Bhagwati

AU - Ramesh, Ramamoorthy

AU - Vecchiola, Aymeric

AU - Bibes, Manuel

AU - Bouzehouane, Karim

AU - Fusil, Stephane

AU - Garcia, Vincent

AU - Young, Ian A.

AU - Casanova, Fèlix

PY - 2024/12

Y1 - 2024/12

N2 - As CMOS technologies face challenges in dimensional and voltage scaling, the demand for novel logic devices has never been greater, with spin-based devices offering scaling potential, at the cost of significantly high switching energies. Alternatively, magnetoelectric materials are predicted to enable low-power magnetization control, a solution with limited device-level results. Here, we demonstrate voltage-based magnetization switching and reading in nanodevices at room temperature, enabled by exchange coupling between multiferroic BiFeO3 and ferromagnetic CoFe, for writing, and spin-to-charge current conversion between CoFe and Pt, for reading. We show that, upon the electrical switching of the BiFeO3, the magnetization of the CoFe can be reversed, giving rise to different voltage outputs. Through additional microscopy techniques, magnetization reversal is linked with the polarization state and antiferromagnetic cycloid propagation direction in the BiFeO3. This study constitutes the building block for magnetoelectric spin-orbit logic, opening a new avenue for low-power beyond-CMOS technologies.

AB - As CMOS technologies face challenges in dimensional and voltage scaling, the demand for novel logic devices has never been greater, with spin-based devices offering scaling potential, at the cost of significantly high switching energies. Alternatively, magnetoelectric materials are predicted to enable low-power magnetization control, a solution with limited device-level results. Here, we demonstrate voltage-based magnetization switching and reading in nanodevices at room temperature, enabled by exchange coupling between multiferroic BiFeO3 and ferromagnetic CoFe, for writing, and spin-to-charge current conversion between CoFe and Pt, for reading. We show that, upon the electrical switching of the BiFeO3, the magnetization of the CoFe can be reversed, giving rise to different voltage outputs. Through additional microscopy techniques, magnetization reversal is linked with the polarization state and antiferromagnetic cycloid propagation direction in the BiFeO3. This study constitutes the building block for magnetoelectric spin-orbit logic, opening a new avenue for low-power beyond-CMOS technologies.

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U2 - 10.1038/s41467-024-45868-x

DO - 10.1038/s41467-024-45868-x

M3 - Article

C2 - 38429273

AN - SCOPUS:85186519419

SN - 2041-1723

VL - 15

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 1902

ER -

Voltage-based magnetization switching and reading in magnetoelectric spin-orbit nanodevices

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