Giant Voltage-induced Modification of Magnetism in Micron-scale Ferromagnetic Metals by Hydrogen Charging

Overview

Journal Nat Commun

Specialty Biology

Date 2020 Sep 25

PMID 32973128

Citations 5

Authors

Xinglong Ye

Harish K Singh

Hongbin Zhang

Holger Gesswein

Mohammed Reda Chellali

Ralf Witte

Alan Molinari

Konstantin Skokov

Oliver Gutfleisch

Horst Hahn

Robert Kruk

Affiliations

Soon will be listed here.

Abstract

Owing to electric-field screening, the modification of magnetic properties in ferromagnetic metals by applying small voltages is restricted to a few atomic layers at the surface of metals. Bulk metallic systems usually do not exhibit any magneto-electric effect. Here, we report that the magnetic properties of micron-scale ferromagnetic metals can be modulated substantially through electrochemically-controlled insertion and extraction of hydrogen atoms in metal structure. By applying voltages of only ~ 1 V, we show that the coercivity of micrometer-sized SmCo, as a bulk model material, can be reversibly adjusted by ~ 1 T, two orders of magnitudes larger than previously reported. Moreover, voltage-assisted magnetization reversal is demonstrated at room temperature. Our study opens up a way to control the magnetic properties in ferromagnetic metals beyond the electric-field screening length, paving its way towards practical use in magneto-electric actuation and voltage-assisted magnetic storage.

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