Polarization memory in the nonpolar magnetic ground state of multiferroic CuFeO2

We investigate polarization memory effects in single-crystal CuFeO2, which has a magnetically induced ferroelectric phase at low temperatures and applied B fields between 7.5 and 13 T. Following electrical poling of the ferroelectric phase, we find that the nonpolar collinear antiferromagnetic groun...

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Veröffentlicht in:	Physical review. B 2016-10, Vol.94 (14), p.144411
Hauptverfasser:	Beilsten-Edmands, J, Magorrian, S J, onda, F R, Prabhakaran, D, Radaelli, P G, Johnson, R D
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Sprache:	eng
Schlagworte:	Antiferromagnetism Bias Computer simulation Deoxidizing Domain walls Ferroelectric materials Ferroelectricity Ground state Helicity Polarization Single crystals
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creator	Beilsten-Edmands, J Magorrian, S J onda, F R Prabhakaran, D Radaelli, P G Johnson, R D
description	We investigate polarization memory effects in single-crystal CuFeO2, which has a magnetically induced ferroelectric phase at low temperatures and applied B fields between 7.5 and 13 T. Following electrical poling of the ferroelectric phase, we find that the nonpolar collinear antiferromagnetic ground state at B=0 T retains a strong memory of the polarization magnitude and direction, such that upon reentering the ferroelectric phase a net polarization of comparable magnitude to the initial polarization is recovered in the absence of external bias. This memory effect is very robust: in pulsed-magnetic-field measurements, several pulses into the ferroelectric phase with reverse bias are required to switch the polarization direction, with significant switching only seen after the system is driven out of the ferroelectric phase and ground state either magnetically (by application of B>13 T) or thermally. The memory effect is also largely insensitive to the magnetoelastic domain composition, since no change in the memory effect is observed for a sample driven into a single-domain state by application of stress in the [11¯0] direction. On the basis of Monte Carlo simulations of the ground-state spin configurations, we propose that the memory effect is due to the existence of helical domain walls within the nonpolar collinear antiferromagnetic ground state, which would retain the helicity of the polar phase for certain magnetothermal histories.
doi_str_mv	10.1103/PhysRevB.94.144411
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Following electrical poling of the ferroelectric phase, we find that the nonpolar collinear antiferromagnetic ground state at B=0 T retains a strong memory of the polarization magnitude and direction, such that upon reentering the ferroelectric phase a net polarization of comparable magnitude to the initial polarization is recovered in the absence of external bias. This memory effect is very robust: in pulsed-magnetic-field measurements, several pulses into the ferroelectric phase with reverse bias are required to switch the polarization direction, with significant switching only seen after the system is driven out of the ferroelectric phase and ground state either magnetically (by application of B>13 T) or thermally. The memory effect is also largely insensitive to the magnetoelastic domain composition, since no change in the memory effect is observed for a sample driven into a single-domain state by application of stress in the [11¯0] direction. On the basis of Monte Carlo simulations of the ground-state spin configurations, we propose that the memory effect is due to the existence of helical domain walls within the nonpolar collinear antiferromagnetic ground state, which would retain the helicity of the polar phase for certain magnetothermal histories.</description><identifier>ISSN: 2469-9950</identifier><identifier>EISSN: 2469-9969</identifier><identifier>DOI: 10.1103/PhysRevB.94.144411</identifier><language>eng</language><publisher>College Park: American Physical Society</publisher><subject>Antiferromagnetism ; Bias ; Computer simulation ; Deoxidizing ; Domain walls ; Ferroelectric materials ; Ferroelectricity ; Ground state ; Helicity ; Polarization ; Single crystals</subject><ispartof>Physical review. 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B</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Beilsten-Edmands, J</au><au>Magorrian, S J</au><au>onda, F R</au><au>Prabhakaran, D</au><au>Radaelli, P G</au><au>Johnson, R D</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Polarization memory in the nonpolar magnetic ground state of multiferroic CuFeO2</atitle><jtitle>Physical review. B</jtitle><date>2016-10-12</date><risdate>2016</risdate><volume>94</volume><issue>14</issue><spage>144411</spage><pages>144411-</pages><issn>2469-9950</issn><eissn>2469-9969</eissn><abstract>We investigate polarization memory effects in single-crystal CuFeO2, which has a magnetically induced ferroelectric phase at low temperatures and applied B fields between 7.5 and 13 T. Following electrical poling of the ferroelectric phase, we find that the nonpolar collinear antiferromagnetic ground state at B=0 T retains a strong memory of the polarization magnitude and direction, such that upon reentering the ferroelectric phase a net polarization of comparable magnitude to the initial polarization is recovered in the absence of external bias. This memory effect is very robust: in pulsed-magnetic-field measurements, several pulses into the ferroelectric phase with reverse bias are required to switch the polarization direction, with significant switching only seen after the system is driven out of the ferroelectric phase and ground state either magnetically (by application of B>13 T) or thermally. The memory effect is also largely insensitive to the magnetoelastic domain composition, since no change in the memory effect is observed for a sample driven into a single-domain state by application of stress in the [11¯0] direction. 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subjects	Antiferromagnetism Bias Computer simulation Deoxidizing Domain walls Ferroelectric materials Ferroelectricity Ground state Helicity Polarization Single crystals
title	Polarization memory in the nonpolar magnetic ground state of multiferroic CuFeO2
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