Room-Temperature Multiferroic Hexagonal<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML" display="inline"><mml:msub><mml:mi>LuFeO</mml:mi><mml:mn>3</mml:mn></mml:msub></mml:math>Films

Wang, Wenbin; Zhao, Jun; Wang, Wenbo; Gai, Zheng; Balke, Nina; Chi, Miaofang; Lee, Ho Nyung; Wang, Tian; Zhu, Leyi; Cheng, Xuemei; Keavney, D. J.; Yi, Jaichul; Ward, Thomas Z.; Snijders, Paul C.; Christen, H. M.; Wu, Weida; Shen, Jian; Xu, Xiaoshan

doi:10.1103/physrevlett.110.237601

Cited by 207 publications

(184 citation statements)

References 31 publications

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“…As both (100) and (101) reflections were observed at low temperature, the resolution-corrected integrated intensities were refined using a two-representation model with basis vectors of both the A 1 and A 2 representations, thereby allowing for rotation of the moments in the plane while requiring only two free parameters after scaling to the integrated intensities of several nuclear reflections. At 5 K the moments are found to be coherently rotated in the a-b plane 25 (5) • from the pure A 2 configuration toward the A 1 with m = 3.55 (9) could not be determined here and was thus fixed to zero in these refinements; this is consistent with a ferromagnetic moment less than 0.1μ B /Fe based upon recent studies of thin films [13][14][15][16], whose intensity is further suppressed by the structure factor for the special position of the transition metal species.…”

Section: A Lufe 1−x Mn X Osupporting

confidence: 57%

“…Recent ab initio calculations [12] have suggested that the closely related family of hexagonal ferrites such as LuFeO 3 (h-LFO) may exhibit greatly enhanced magnetic properties relative to their manganite counterparts due to enhanced exchange interactions, larger localized magnetic moments, and differences in the local electronic anisotropy between Mn 3+ and Fe 3+ . In fact, recent investigations of thin films of h-LFO demonstrate that magnetic order occurs as high as 150 K with the simultaneous appearance of a net ferromagnetic (FM) moment parallel to the ferroelectric axis [13][14][15][16] consistent with ab initio calculations [12]. To date, studies of this material have been limited to thin films as h-LuFeO 3 is metastable in bulk and instead forms the centrosymmetric and nonpolar orthorhombic Pbnm structure, precluding ferroelectricity [17].…”

Section: Introductionmentioning

confidence: 99%

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Multiferroicity in doped hexagonalLuFeO3

et al. 2015

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The hexagonal phase of LuFeO 3 is a rare example of a multiferroic material possessing a weak ferromagnetic moment, which is predicted to be switchable by an electric field. We stabilize this structure in bulk form though Mn and Sc doping, and determine the complete magnetic and crystallographic structures using neutron-scattering and magnetometry techniques. The ferroelectric P 6 3 cm space group is found to be stable over a wide concentration range, ordering antiferromagnetically with Néel temperatures that smoothly increase following the ratio of c to a (c/a) lattice parameters up to 172 K, the highest found in this class of materials to date. The magnetic structure for a range of temperatures and dopings is consistent with recent studies of high quality epitaxial films of pure hexagonal LuFeO 3 including a ferromagnetic moment parallel to the ferroelectric axis. We propose a mechanism by which room-temperature multiferroicity could be achieved in this class of materials.

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Section: A Lufe 1−x Mn X Osupporting

confidence: 57%

Section: Introductionmentioning

confidence: 99%

Multiferroicity in doped hexagonalLuFeO3

et al. 2015

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“…In a recent study on hLuFeO 3 , strong exchange coupling leading to high magnetic transition temperatures and spin re-orientation transitions closely connected with structural distortions have been identified [16]. Thin films of hLuFeO 3 have shown evidence for a room temperature multiferroic [17] and has been identified as a strong candidate for linear magnetoelectric coupling and control of the ferromagnetic moment directly by an electric field [18]. However, bulk LuFeO 3 normally crystallizes in orthorhombic P bnm symmetry thereby precluding the possibility of ferroelectricity.…”

Section: Pacs Numbersmentioning

confidence: 99%

Spin-lattice coupling and frustrated magnetism in Fe-doped hexagonal LuMnO ₃

Nair¹,

Fu²,

Kumar³

et al. 2015

EPL

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Strong spin-lattice coupling and prominent frustration effects observed in the 50% Fe-doped frustrated hexagonal (h)LuMnO3 are reported. A Néel transition at TN ≈ 112 K and a possible spin re-orientation transition at TSR ≈ 55 K are observed in the magnetization data. From neutron powder diffraction data, the nuclear structure at and below 300 K was refined in polar P 63cm space group. While the magnetic structure of LuMnO3 belongs to the Γ4 (P 6 3 c m) representation, that of LuFe0.5Mn0.5O3 belongs to Γ1 (P 63cm) which is supported by the strong intensity for the (100) reflection and also judging by the presence of spin-lattice coupling. The refined atomic positions for Lu and Mn/Fe indicate significant atomic displacements at TN and TSR which confirms strong spin-lattice coupling. Our results complement the discovery of room temperature multiferroicity in thin films of hLuFeO3 and would give impetus to study LuFe1−xMnxO3 systems as potential multiferroics where electric polarization is linked to giant atomic displacements.

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“…Using epitaxial stabilization, however, it is possible to make a metastable hexagonal polymorph of LuFeO 3 that is isostructural with YMnO 3 and other hexagonal rare-earth manganites. 21 In this hexagonal structure, LuFeO 3 has been measured to be both ferroelectric 22,23 and weakly ferromagnetic, [22][23][24] with first principles calculations predicting the ability to reverse the magnetization with a change in polarization. 25 It was recently reported that h-LuFeO 3 is antiferromagnetically ordered at room temperature with a canted antiferromagnetic ordering at T N = 130 K, 23 making it one of the few known room-temperature multiferroics (in this work we will refer to the onset of canted antiferromagnetic order, which is what we can measure, as the Néel temperature).…”

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confidence: 99%