Giant magnetoelectricity in soft materials using hard magnetic soft materials

Amir Hossein Rahmati; Rong Jia; Kai Tan; Liping Liu; Xuanhe Zhao; Qian Deng; Pradeep Sharma

doi:10.1016/j.mtphys.2023.100969

Giant magnetoelectricity in soft materials using hard magnetic soft materials

Amir Hossein Rahmati, Rong Jia, Kai Tan, Liping Liu, Xuanhe Zhao, Qian Deng, Pradeep Sharma

School of Arts and Sciences, Mathematics

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

23 Scopus citations

Abstract

Imagine a material that will produce electricity via a contactless, wireless signal. Further, we hope that this material is capable of large deformation reminiscent of soft robots and is soft enough to conform to irregular or curved geometries. This would all be possible if soft magnetoelectric materials were available; paving the way for applications such as remote drug delivery, energy harvesting, soft robots, multiple state memories among others. Here, for the first time, using the concept of hard magnetic soft matter in combination with electrets, we design and create a soft magnetoelectric material that exhibits an extremely strong, self-biased magnetoelectric effect. Further, using programmable pattern of deposition of magnetic dipoles and charges, we report a giant magnetoelectric coefficient in an ultra-soft deformable material that retains its strength even under infinitesimal external fields and at low frequencies.

Original language	English (US)
Article number	100969
Journal	Materials Today Physics
Volume	31
DOIs	https://doi.org/10.1016/j.mtphys.2023.100969
State	Published - Feb 2023

All Science Journal Classification (ASJC) codes

General Materials Science
Energy (miscellaneous)
Physics and Astronomy (miscellaneous)

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10.1016/j.mtphys.2023.100969

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title = "Giant magnetoelectricity in soft materials using hard magnetic soft materials",

abstract = "Imagine a material that will produce electricity via a contactless, wireless signal. Further, we hope that this material is capable of large deformation reminiscent of soft robots and is soft enough to conform to irregular or curved geometries. This would all be possible if soft magnetoelectric materials were available; paving the way for applications such as remote drug delivery, energy harvesting, soft robots, multiple state memories among others. Here, for the first time, using the concept of hard magnetic soft matter in combination with electrets, we design and create a soft magnetoelectric material that exhibits an extremely strong, self-biased magnetoelectric effect. Further, using programmable pattern of deposition of magnetic dipoles and charges, we report a giant magnetoelectric coefficient in an ultra-soft deformable material that retains its strength even under infinitesimal external fields and at low frequencies.",

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T1 - Giant magnetoelectricity in soft materials using hard magnetic soft materials

AU - Rahmati, Amir Hossein

AU - Jia, Rong

AU - Tan, Kai

AU - Liu, Liping

AU - Zhao, Xuanhe

AU - Deng, Qian

AU - Sharma, Pradeep

PY - 2023/2

Y1 - 2023/2

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AB - Imagine a material that will produce electricity via a contactless, wireless signal. Further, we hope that this material is capable of large deformation reminiscent of soft robots and is soft enough to conform to irregular or curved geometries. This would all be possible if soft magnetoelectric materials were available; paving the way for applications such as remote drug delivery, energy harvesting, soft robots, multiple state memories among others. Here, for the first time, using the concept of hard magnetic soft matter in combination with electrets, we design and create a soft magnetoelectric material that exhibits an extremely strong, self-biased magnetoelectric effect. Further, using programmable pattern of deposition of magnetic dipoles and charges, we report a giant magnetoelectric coefficient in an ultra-soft deformable material that retains its strength even under infinitesimal external fields and at low frequencies.

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Giant magnetoelectricity in soft materials using hard magnetic soft materials

Abstract

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