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Main Authors: Zeng, Z., Först, M., Fechner, M., Prabhakaran, D., Radaelli, P. G., Cavalleri, A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.10682
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author Zeng, Z.
Först, M.
Fechner, M.
Prabhakaran, D.
Radaelli, P. G.
Cavalleri, A.
author_facet Zeng, Z.
Först, M.
Fechner, M.
Prabhakaran, D.
Radaelli, P. G.
Cavalleri, A.
contents Ultrafast switching of ferroic phases is an important research frontier, with significant technological potential. Yet, current efforts are meeting some key challenges, ranging from limited speeds in ferromagnets to intrinsic volatility of switched domains due to uncompensated depolarizing fields in ferroelectrics. Unlike these ferroic systems, ferroaxial materials host bistable states that do not break spatial-inversion or time-reversal symmetry, and are therefore immune to depolarizing fields. Yet, they are difficult to manipulate because external axial fields are not easily constructed with conventional methods. Here, we demonstrate ultrafast switching of ferroaxial order by engineering an effective axial field made up of circularly driven terahertz phonon modes. A switched ferroaxial domain remains stable for many hours and can be reversed back with a second terahertz pulse of opposite helicity. The effects demonstrated here may lead to a new platform for ultrafast information storage.
format Preprint
id arxiv_https___arxiv_org_abs_2506_10682
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Ultrafast non-volatile rewritable ferroaxial switching
Zeng, Z.
Först, M.
Fechner, M.
Prabhakaran, D.
Radaelli, P. G.
Cavalleri, A.
Materials Science
Ultrafast switching of ferroic phases is an important research frontier, with significant technological potential. Yet, current efforts are meeting some key challenges, ranging from limited speeds in ferromagnets to intrinsic volatility of switched domains due to uncompensated depolarizing fields in ferroelectrics. Unlike these ferroic systems, ferroaxial materials host bistable states that do not break spatial-inversion or time-reversal symmetry, and are therefore immune to depolarizing fields. Yet, they are difficult to manipulate because external axial fields are not easily constructed with conventional methods. Here, we demonstrate ultrafast switching of ferroaxial order by engineering an effective axial field made up of circularly driven terahertz phonon modes. A switched ferroaxial domain remains stable for many hours and can be reversed back with a second terahertz pulse of opposite helicity. The effects demonstrated here may lead to a new platform for ultrafast information storage.
title Ultrafast non-volatile rewritable ferroaxial switching
topic Materials Science
url https://arxiv.org/abs/2506.10682