Antiferromagnetic phase of the gapless semiconductor<mml:math xmlns:mml="http://www.w3.org/1998/Math/MathML"><mml:mrow><mml:msub><mml:mi mathvariant="normal">V</mml:mi><mml:mn>3</mml:mn></mml:msub><mml:mi>Al</mml:mi></mml:mrow></mml:math>

Jamer, Michelle E.; Assaf, Badih A.; Sterbinsky, George E.; Arena, D. A.; Lewis, L. H.; Saúl, Andrés; Radtke, Guillaume

doi:10.1103/physrevb.91.094409

Cited by 32 publications

(28 citation statements)

References 28 publications

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“…3,[13][14][15][16] Among the discovered materials, fully compensated ferrimagnetic (FCF) materials have gained a lot of interest recently. [17][18][19] Leuken and Groot showed theoretically that this new class of materials can show 100 % spin polarization without having a net magnetic moment, and hence given the name half metallic antiferromagnetic materials or fully compensated ferrimagnets. 20 However, for the antiferromagnets, symmetry demands the same density of states (DOS) for spin up and spin down bands.…”

Section: Introductionmentioning

confidence: 99%

Competing magnetic and spin-gapless semiconducting behavior in fully compensated ferrimagnetic CrVTiAl: Theory and experiment

et al. 2018

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We report the structural, magnetic and transport properties of polycrystalline CrVTiAl alloy along with first principles calculations. It crystallizes in the LiMgPdSn type structure with lattice parameter 6.14Å at room temperature. Absence of (111) peak along with the presence of a weak (200) peak indicates the antisite disorder of Al with Cr and V atoms. The magnetization measurements reveal a ferrimagnetic transition near 710 K and a coercive field of 100 Oe at 3 K. Very low moment and coercive field indicate fully compensated ferrimagnetism in the alloy. Temperature coefficient of resistivity is found to be negative, indicating a characteristic of semiconducting nature. Absence of exponential dependence of resistivity on temperature indicates a gapless/spin-gapless semiconducting behaviour. Electronic and magnetic properties of CrVTiAl for three possible crystallograpic configurations are studied theoretically. All the three configurations are found to be different forms of semiconductors. Ground state configuration is a fully compensated ferrimagnet with band gaps 0.58 eV and 0.30 eV for up and down spin bands respectively. The next higher energy configuration is also ferrimagnetic, but has spin-gapless semiconducting nature. The highest energy configuration corresponds to a non-magnetic gapless semiconductor. The energy differences among these configurations are quite small (< 1 mRy/atom) which hints that at finite temperatures, the alloy exists in a disordered phase, which is a mixture of the three configurations. By taking into account the theoretical and the experimental findings, we conclude that CrVTiAl is a fully compensated ferrimagnet with predominantly spin-gapless semiconductor nature.

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Section: Introductionmentioning

confidence: 99%

Competing magnetic and spin-gapless semiconducting behavior in fully compensated ferrimagnetic CrVTiAl: Theory and experiment

et al. 2018

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“…In contrast traditional Néel antiferromagnets cannot be spin-polarized due to their symmetric anti-aligned moments resulting in a symmetric DOS, which was demonstrated in the DOS of the gapless semiconductor V 3 Al. [10,11] Unfortunately, recent research has shown that some HMFF compounds tend to be unstable and decompose into more stable states, in addition to possessing properties that are adversely affected by structural disorder. [12][13][14] This current work focuses on the synthesis and characterization of Cr 2 CoAl, which has been predicted to be a HMFF when it adopts the inverse Heusler structure.…”

Section: Introductionmentioning

confidence: 99%

Low-moment ferrimagnetic phase of the Heusler compound Cr2CoAl

Jamer

Marshall

Sterbinsky

et al. 2015

Journal of Magnetism and Magnetic Materials

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Synthesizing half-metallic fully-compensated ferrimagnets that form in the inverse Heusler phase could lead to superior spintronic devices. These materials would have high spin polarization at room temperature with very little fringing magnetic fields. Previous theoretical studies indicated that Cr2CoAl should form in a stable inverse Heusler lattice due to its low activation energy. Here, stoichiometric Cr2CoAl samples were arc-melted and annealed at varying temperatures, followed by studies of their structural and magnetic properties. High-resolution synchrotron X-ray diffraction revealed a chemically ordered Heusler phase in addition to CoAl and Cr phases. Soft X-ray magnetic circular dichroism revealed that the Cr and Co magnetic moments are antiferromagnetically oriented leading to the observed low magnetic moment in Cr2CoAl.

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“…1 (lower left). [8,9] The D0 3 Mn 3 Al structure is based on the full Heusler space group Fm3m, which has the formula X 2 YZ where X and Y are equal, leading to the formula X 3 Z. [10] Recently, D0 3 -type V 3 Al was synthesized and determined to behave as a gapless semiconductor, where both the majority (red) and minority (blue) bands in the DOS are symmetric, prohibiting spin polarization as depicted in Fig.…”

Section: Introductionmentioning

confidence: 99%

Compensated Ferrimagnetism in the Zero-Moment Heusler Alloy Mn3Al

et al. 2017

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While antiferromagnets have been proposed as components to limit stray magnetic fields, their inability to be spin polarized inhibits their use in spintronic devices. Compensated ferrimagnets are a unique solution to this dilemma since they have zero net moment, but their nonsymmetric density of states allows achievement of full spin polarization. Density functional theory predicts Mn3Al in the D03 structure to be fully compensated and retain half-metallicity at room temperature. In this work, 50 nm Mn3Al thin films were synthesized using molecular beam epitaxy and annealed at various temperatures in order to investigate their magnetic properties. Magnetometry measurements confirmed the high Curie temperature of 605 K. Polarized neutron reflectometry (PNR) indicated a low net magnetic moment, along with depth profiles of the structure and magnetization. From the PNR data, we extract a saturation moment of 0.11 ± 0.04 µB/f.u., confirming the nominal zero moment present in these thin films.

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Antiferromagnetic phase of the gapless semiconductorV3Al

Cited by 32 publications

References 28 publications

Competing magnetic and spin-gapless semiconducting behavior in fully compensated ferrimagnetic CrVTiAl: Theory and experiment

Competing magnetic and spin-gapless semiconducting behavior in fully compensated ferrimagnetic CrVTiAl: Theory and experiment

Low-moment ferrimagnetic phase of the Heusler compound Cr2CoAl

Compensated Ferrimagnetism in the Zero-Moment Heusler Alloy Mn3Al

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