Imaging and ferroelectric orientation mapping of photostriction in a single bismuth ferrite nanocrystal
Imaging and ferroelectric orientation mapping of photostriction in a single bismuth ferrite nanocrystal
The exploration of multiferroic materials and their interaction with light at the nanoscale presents a captivating frontier in materials science. Bismuth Ferrite (BiFeO3 , BFO), a standout among these materials, exhibits room-temperature ferroelectric and antiferromagnetic behavior and magnetoelectric coupling. Of particular interest is the phenomenon of photostriction, the light-induced deformation of crystal structures, which enhances the prospect for device functionality based on these materials. Understanding and harnessing multiferroic phenomena holds significant promise in various technological applications, from optoelectronics to energy storage. The orientation of the ferroelectric axis is an important design parameter for devices formed from multiferroic materials. Determining its orientation in the laboratory frame of reference usually requires knowing multiple wavevector transfer (Q-Vector) directions, which can be challenging to establish due to the need for extensive reciprocal-space searches. Our study demonstrates a method to uniquely identify the ferroelectric axis orientation using Bragg Coherent X-ray Diffraction Imaging (BCDI) measurements at a single Q-vector direction. This method involves applying photostriction-inducing laser illumination across various laser polarizations. Our findings reveal that photostriction primarily occurs as a surface phenomenon at the nanoscale. Moreover a photo-induced crystal length change ranging from 30 to 60 nm was observed, consistent with earlier findings performed on bulk material.
Mokhtar, Ahmed H.
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Serban, David
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Porter, Daniel G.
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Nisbet, Gareth
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Collins, Steve
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Bombardi, Alexendro
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Newton, Marcus C.
fac92cce-a9f3-46cd-9f58-c810f7b49c7e
7 May 2024
Mokhtar, Ahmed H.
f894fae3-5337-4364-a75d-02c35a3db64d
Serban, David
2206233e-d1ab-4f6a-9d03-989884b529fa
Porter, Daniel G.
70360362-ea3f-40bd-ae01-41dbf0d5ed35
Nisbet, Gareth
f514ec39-aa38-45ff-b70b-90a7d43f20fc
Collins, Steve
b673cfb8-b82d-4736-976f-59219335f50b
Bombardi, Alexendro
ebbc9264-3bf7-484f-b49d-c8c817a0f0af
Newton, Marcus C.
fac92cce-a9f3-46cd-9f58-c810f7b49c7e
Mokhtar, Ahmed H., Serban, David, Porter, Daniel G., Nisbet, Gareth, Collins, Steve, Bombardi, Alexendro and Newton, Marcus C.
(2024)
Imaging and ferroelectric orientation mapping of photostriction in a single bismuth ferrite nanocrystal.
npj Computational Materials, 10 (1), [90].
(doi:10.1038/s41524-024-01287-6).
Abstract
The exploration of multiferroic materials and their interaction with light at the nanoscale presents a captivating frontier in materials science. Bismuth Ferrite (BiFeO3 , BFO), a standout among these materials, exhibits room-temperature ferroelectric and antiferromagnetic behavior and magnetoelectric coupling. Of particular interest is the phenomenon of photostriction, the light-induced deformation of crystal structures, which enhances the prospect for device functionality based on these materials. Understanding and harnessing multiferroic phenomena holds significant promise in various technological applications, from optoelectronics to energy storage. The orientation of the ferroelectric axis is an important design parameter for devices formed from multiferroic materials. Determining its orientation in the laboratory frame of reference usually requires knowing multiple wavevector transfer (Q-Vector) directions, which can be challenging to establish due to the need for extensive reciprocal-space searches. Our study demonstrates a method to uniquely identify the ferroelectric axis orientation using Bragg Coherent X-ray Diffraction Imaging (BCDI) measurements at a single Q-vector direction. This method involves applying photostriction-inducing laser illumination across various laser polarizations. Our findings reveal that photostriction primarily occurs as a surface phenomenon at the nanoscale. Moreover a photo-induced crystal length change ranging from 30 to 60 nm was observed, consistent with earlier findings performed on bulk material.
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Accepted/In Press date: 13 April 2024
Published date: 7 May 2024
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Local EPrints ID: 489361
URI: http://eprints.soton.ac.uk/id/eprint/489361
ISSN: 2057-3960
PURE UUID: cf3af5a1-0910-4c14-81fb-1e8c50547f31
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Date deposited: 22 Apr 2024 16:51
Last modified: 16 May 2024 01:58
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Author:
Ahmed H. Mokhtar
Author:
David Serban
Author:
Daniel G. Porter
Author:
Gareth Nisbet
Author:
Steve Collins
Author:
Alexendro Bombardi
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