Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics

Magneto-ionics, which deals with the change of magnetic properties through voltage-driven ion migration, is expected to be one of the emerging technologies to develop energy-efficient spintronics. While a precise modulation of magnetism is achieved when voltage is applied, much more uncontrolled is...

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Detalles Bibliográficos
Autores principales: Tan, Zhengwei, de Rojas, Julius, Martins, Sofia, Lopeandia, Aitor, Quintana, Alberto, Cialone, Matteo, Herrero-Martín, Javier, Meersschaut, Johan, Vantomme, André, Costa-Krämer, José L., Sort, Jordi, Menéndez, Enric
Formato: Online Artículo Texto
Lenguaje:English
Publicado: The Royal Society of Chemistry 2022
Materias:
Chemistry
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9810105/
https://www.ncbi.nlm.nih.gov/pubmed/36305823
http://dx.doi.org/10.1039/d2mh01087a
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author Tan, Zhengwei
de Rojas, Julius
Martins, Sofia
Lopeandia, Aitor
Quintana, Alberto
Cialone, Matteo
Herrero-Martín, Javier
Meersschaut, Johan
Vantomme, André
Costa-Krämer, José L.
Sort, Jordi
Menéndez, Enric
author_facet Tan, Zhengwei
de Rojas, Julius
Martins, Sofia
Lopeandia, Aitor
Quintana, Alberto
Cialone, Matteo
Herrero-Martín, Javier
Meersschaut, Johan
Vantomme, André
Costa-Krämer, José L.
Sort, Jordi
Menéndez, Enric
author_sort Tan, Zhengwei
collection PubMed
description Magneto-ionics, which deals with the change of magnetic properties through voltage-driven ion migration, is expected to be one of the emerging technologies to develop energy-efficient spintronics. While a precise modulation of magnetism is achieved when voltage is applied, much more uncontrolled is the spontaneous evolution of magneto-ionic systems upon removing the electric stimuli (i.e., post-stimulated behavior). Here, we demonstrate a voltage-controllable N ion accumulation effect at the outer surface of CoN films adjacent to a liquid electrolyte, which allows for the control of magneto-ionic properties both during and after voltage pulse actuation (i.e., stimulated and post-stimulated behavior, respectively). This effect, which takes place when the CoN film thickness is below 50 nm and the voltage pulse frequency is at least 100 Hz, is based on the trade-off between generation (voltage ON) and partial depletion (voltage OFF) of ferromagnetism in CoN by magneto-ionics. This novel effect may open opportunities for new neuromorphic computing functions, such as post-stimulated neural learning under deep sleep.
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spelling pubmed-98101052023-01-20 Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics Tan, Zhengwei de Rojas, Julius Martins, Sofia Lopeandia, Aitor Quintana, Alberto Cialone, Matteo Herrero-Martín, Javier Meersschaut, Johan Vantomme, André Costa-Krämer, José L. Sort, Jordi Menéndez, Enric Mater Horiz Chemistry Magneto-ionics, which deals with the change of magnetic properties through voltage-driven ion migration, is expected to be one of the emerging technologies to develop energy-efficient spintronics. While a precise modulation of magnetism is achieved when voltage is applied, much more uncontrolled is the spontaneous evolution of magneto-ionic systems upon removing the electric stimuli (i.e., post-stimulated behavior). Here, we demonstrate a voltage-controllable N ion accumulation effect at the outer surface of CoN films adjacent to a liquid electrolyte, which allows for the control of magneto-ionic properties both during and after voltage pulse actuation (i.e., stimulated and post-stimulated behavior, respectively). This effect, which takes place when the CoN film thickness is below 50 nm and the voltage pulse frequency is at least 100 Hz, is based on the trade-off between generation (voltage ON) and partial depletion (voltage OFF) of ferromagnetism in CoN by magneto-ionics. This novel effect may open opportunities for new neuromorphic computing functions, such as post-stimulated neural learning under deep sleep. The Royal Society of Chemistry 2022-10-28 /pmc/articles/PMC9810105/ /pubmed/36305823 http://dx.doi.org/10.1039/d2mh01087a Text en This journal is © The Royal Society of Chemistry https://creativecommons.org/licenses/by-nc/3.0/
spellingShingle Chemistry
Tan, Zhengwei
de Rojas, Julius
Martins, Sofia
Lopeandia, Aitor
Quintana, Alberto
Cialone, Matteo
Herrero-Martín, Javier
Meersschaut, Johan
Vantomme, André
Costa-Krämer, José L.
Sort, Jordi
Menéndez, Enric
Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
title Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
title_full Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
title_fullStr Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
title_full_unstemmed Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
title_short Frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
title_sort frequency-dependent stimulated and post-stimulated voltage control of magnetism in transition metal nitrides: towards brain-inspired magneto-ionics
topic Chemistry
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9810105/
https://www.ncbi.nlm.nih.gov/pubmed/36305823
http://dx.doi.org/10.1039/d2mh01087a
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