Computational screening of Fe-Ta hard magnetic phases

Arapan, Sergiu; Nieves, P.; Herper, Heike C.; Legut, Dominik

doi:10.1103/physrevb.101.014426

Cited by 17 publications

(7 citation statements)

References 45 publications

(46 reference statements)

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“…To determine the origin of the difference in MAE values we analyzed the spin-orbit coupling energy (SOC) of the Co and Mn atoms with their spins oriented along the z and x directions as well as the partial density of states (DOS), similar to the analyses presented in Refs. [46][47][48][49][50][51]. The details of that investigation can be found in Appendix D. Summarizing the results, we find that apart from the Co 3 Mn 2 Ge compound that is listed in the ICSD database, Co 3 Mn 2 Al and Co 3 Mn 2 Ga are also expected to have the properties of a good permanent magnet.…”

Section: Chemical Substitution Of Gementioning

confidence: 84%

“…The later include high magnetocrystalline anisotropy alloys (MnBi [4,5] and MnAl [6,7]), nanostructures [8][9][10][11], thin films [12,13], alnico permanent magnets, and many more [14][15][16][17]. Techniques used for this search include both filtering through a large number of systems [18][19][20][21] and investigating a single or a group of similar compounds [14,15,[22][23][24][25][26][27][28][29]. In Ref.…”

Section: Introductionmentioning

confidence: 99%

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Data-driven design of a new class of rare-earth free permanent magnets

Vishina¹,

Hedlund²,

Shtender³

et al. 2021

Preprint

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A new class of rare-earth-free permanent magnets is proposed. The parent compound of this class is Co3Mn2Ge, and its discovery is the result of first principles theory combined with experimental synthesis and characterisation. The theory is based on a high-throughput/data-mining search among materials listed in the ICSD database. From ab-initio theory of the defect free material it is predicted that the saturation magnetization is 1.71 T, the uniaxial magnetocrystalline anisotropy is 1.44 MJ/m 3 , and the Curie temperature is 700 K. Co3Mn2Ge samples were then synthesized and characterised with respect to structure and magnetism. The crystal structure was found to be the MgZn2-type, with partial disorder of Co and Ge on the crystallographic lattice sites. From magnetization measurements a saturation polarization of 0.86 T at 10 K was detected, together with a uniaxial magnetocrystalline anisotropy constant of 1.18 MJ/m 3 , and the Curie temperature of TC = 359 K. These magnetic properties make Co3Mn2Ge a very promising material as a rare-earth free permanent magnet, and since we can demonstrate that magnetism depends critically on the amount of disorder of the Co and Ge atoms, a further improvement of the magnetism is possible. From the theoretical works, a substitution of Ge by neighboring elements suggest two other promising materials -Co3Mn2Al and Co3Mn2Ga. We demonstrate here that the class of compounds based on T3Mn2X (T = Co or alloys between Fe and Ni; X=Ge, Al or Ga) in the MgZn2 structure type, form a new class of rare-earth free permanent magnets with very promising performance.

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Section: Chemical Substitution Of Gementioning

confidence: 84%

Section: Introductionmentioning

confidence: 99%

Data-driven design of a new class of rare-earth free permanent magnets

Vishina¹,

Hedlund²,

Shtender³

et al. 2021

Preprint

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“…For instance, within the NOVAMAG project, the evolutionary algorithm has been applied to predict novel permanent materials, leading to Fe 3 Ta and Fe 5 Ta as promising candidates. 61 To summarize, HTP calculations can be performed to validate the stability of known compounds and to predict possible new compounds. The pending challenges are (a) how to systematically address the stability and metastability, ideally with phase diagrams optimized incorporating existing experimental data, (b) how to extent to the multicomponent cases with chemical disorder and thus entropic free energy, so that the stability of high entropy alloys 62 is accessible, and (c) how to perform proper evaluation of the thermodynamic stability for correlated RE compounds and transition metal oxides.…”

Section: Dynamical Stability Which Describes the Stabilitymentioning

confidence: 99%

“…There have been well established methods as implemented in USPEX [56] and CALYPSO [57] to predict possible crystal structures. For instance, within the NOVAMAG project, the evolutionary algorithm has been applied to predict novel permanent materials, leading to Fe 3 Ta and Fe 5 Ta as promising candidates [58].…”

Section: New Compounds and Phase Diagrammentioning

confidence: 99%

High-throughput design of magnetic materials

Zhang

2021

Electron. Struct.

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Materials design based on density functional theory (DFT) calculations is an emergent field of great potential to accelerate the development and employment of novel materials. Magnetic materials play an essential role in green energy applications as they provide efficient ways of harvesting, converting, and utilizing energy. In this review, after a brief introduction to the major functionalities of magnetic materials, we demonstrated how the fundamental properties can be tackled via high-throughput DFT calculations, with a particular focus on the current challenges and feasible solutions. Successful case studies are summarized on several classes of magnetic materials, followed by bird-view perspectives.

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“…Fe-rich Fe-Mn alloys with hcp structure (ǫ phase) shows the Néel temperature of 230 K. 30 ǫ-Fe-X alloys (X = Ru, and Os) have AFM ground states at ambient pressure with Néel temperatures of ∼100 K. Fe 2 Ta alloy exhibits a paramagnetic state in which either an excess of Fe or Ta can induce ferromagnetic ordering at low temperatures (∼150 K). 31,32 Iron hydride FeH with a double hcp (dhcp) structure exhibit a ferromagnetic ground state under pressure. [33][34][35] On the other hand, no internal magnetic field has been detected for hcp Fe-Ni alloy, even at 11 K under 21 GPa.…”

Section: Introductionmentioning

confidence: 99%

Origin of phase stability in Fe with long-period stacking order as an intermediate phase in cyclic $γ$-$ε$ martensitic transformation

Tsumuraya,

Watanabe,

Sawaguchi

2020

Preprint

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Computational screening of Fe-Ta hard magnetic phases

Cited by 17 publications

References 45 publications

Data-driven design of a new class of rare-earth free permanent magnets

Data-driven design of a new class of rare-earth free permanent magnets

High-throughput design of magnetic materials

Origin of phase stability in Fe with long-period stacking order as an intermediate phase in cyclic $γ$-$ε$ martensitic transformation

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