Magnetic, optical, and magneto-optical properties of Mn<i>X</i>(<i>X</i>=As, Sb, or Bi) from full-potential calculations

Ravindran, P.; Delin, Anna; James, P.; Johansson, Börje; Wills, J. M.; Ahuja, Rajeev; Eriksson, Olle

doi:10.1103/physrevb.59.15680

Cited by 151 publications

(132 citation statements)

References 81 publications

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“…2, the magnetic moment of the Mn atom shows a small temperature dependence in the range from 10 to 300 K. The magnetic moment per Mn is 3.60 B and 4.18 B at room temperature and 10 K, which is well in agreement with the magnetic measurements on polycrystalline MnBi, 4,8 on single crystals, 15 and with theoretical band calculations. 17,18 The value at room temperature ͑RT͒ is considerably less than that obtained by previous neutron diffraction measurements, 7 where a value of 4.5 B was claimed at RT. Below 200 K, the magnetic moments of Mn deviate gradually from the direction parallel to the c axis and into the direction nearly perpendicular to the c axis at 50 K. A sharp increase of the angle between Mn magnetic moments and the c axis is observed around 90 K. However, the magnetic moment still shows a very small c-axis component at 10 K, i.e., it is not totally in the basal plane.…”

Section: Resultsmentioning

confidence: 41%

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Structure and magnetic properties of the MnBi low temperature phase

Yang

Yelon

James

et al. 2002

Journal of Applied Physics

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High purity MnBi low temperature phase has been prepared and analyzed using magnetic measurements and neutron diffraction. The low-temperature phase of the MnBi alloy has a coercivity μ0iHc of 2.0 T at 400 K, and exhibits a positive temperature coefficient from 0 to at least 400 K. The neutron data refinement indicated that the Mn atom changes its spin direction from c axis above room temperature to nearly perpendicular to the c axis at 50 K. A canted magnetic structure has been observed below 200 K. The anisotropy field increases with increasing temperature which gives rise to a high coercivity at the higher temperatures. The anisotropic bonded magnets have maximum energy products (BH)max of 7.7 and 4.6 MGOe at room temperature and 400 K, respectively.

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Section: Resultsmentioning

confidence: 41%

“…Additionally, recent band calculations with spin-orbital coupling and orbital polarization still result in disagreement between theoretical and experimental results. 18 Further studies regarding the temperature dependence of the anisotropy of MnBi are necessary.…”

Section: 1519mentioning

confidence: 99%

Structure and magnetic properties of the MnBi low temperature phase

Yang

Yelon

James

et al. 2002

Journal of Applied Physics

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“…The calculated optical parameters have more spectral structure [38][39][40][41] than what is commonly observed because no fluctuations are included. To facilitate comparison with experimental data, the calculated optical spectra is smoothed by broadening.…”

Section: Optical Propertiesmentioning

confidence: 92%

Phase stability, electronic structure, and optical properties of indium oxide polytypes

et al. 2007

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Structural phase stability, electronic structure, optical properties, and high-pressure behavior of polytypes of In 2 O 3 in three space group symmetry I2 1 3, Ia3 and R3 are studied by first-principles density functional calculations. From structural optimization studies lattice and positional parameters have been calculated, which are found to be in good agreement with the corresponding experimental data. In 2 O 3 of space group symmetry I2 1 3 and Ia3 are shown to undergo a pressureinduced phase transition to IO3 at pressures around 3.83 GPa. From analysis of band structure it is found that In 2 O 3 of space group symmetry I2 1 3 is indirect band gap semiconductors, while the other phase of space group Ia3 is direct band gap. The calculated carrier effective masses for all these three phases are compared with available experimental and theoretical values. From chargedensity and electron localization function analysis it is found that these phases have dominant ionic bonding. The magnitude of the absorption and reflection coefficients of In 2 O 3 with space group Ia3 and R3 are small in the energy range 0-5 eV, so that these materials can re regarded and classified as transparent.

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“…However, it is highly desirable to explore new halfmetallic ferromagnetic materials which are compatible with important III-V and II-VI semiconductors. For this purpose, effort has be made on the metastable zincblende (B3) phases such as the transition-metal pnictides [10,11,12,13,14,15,16,17,18,19,20]. Although zincblende phases of MnAs [11], CrAs [12,13] and CrSb [14] have been successfully fabricated as nanodots, ultrathin films and ultrathin layers in multilayers, it has not been possible to grow the zincblende half-metallic ferromagnetic phases as high-quality layers or thick films.…”

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confidence: 99%

Half-Metallic Ferromagnetism and Structural Stability of Zincblende Phases of the Transition-Metal Chalcogenides

et al. 2003

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An accurate density-functional method is used to study systematically half-metallic ferromagnetism and stability of zincblende phases of 3d-transition-metal chalcogenides. The zincblende CrTe, CrSe, and VTe phases are found to be excellent half-metallic ferromagnets with large halfmetallic gaps (up to 0.88 eV). They are mechanically stable and approximately 0.31-0.53 eV per formula unit higher in total energy than the corresponding nickel-arsenide ground-state phases, and therefore would be grown epitaxially in the form of films and layers thick enough for spintronic applications.PACS numbers: 75.90.+w, 62.25.+g, 73.22.-f, 75.30.-m Phys Rev Lett 91, 037204 (2003) Half-metallic ferromagnets are seen as a key ingredient in future high performance spintronic devices, because they have only one electronic spin channel at the Fermi energy and, therefore, may show nearly 100 % spin polarization [1,2]. Since de Groot et al's discovery [3] in 1983, a lot of half-metallic ferromagnets have been theoretically predicted and some of them furthermore have been confirmed experimentally [4,5,6,7]. Much attention has been paid to understanding the mechanism behind the half-metallic magnetism and to studying its implication on various physical properties [8,9]. However, it is highly desirable to explore new halfmetallic ferromagnetic materials which are compatible with important III-V and II-VI semiconductors. For this purpose, effort has be made on the metastable zincblende (B3) phases such as the transition-metal pnictides [10,11,12,13,14,15,16,17,18,19,20]. Although zincblende phases of MnAs [11], CrAs [12,13] and CrSb [14] have been successfully fabricated as nanodots, ultrathin films and ultrathin layers in multilayers, it has not been possible to grow the zincblende half-metallic ferromagnetic phases as high-quality layers or thick films. This is due to the metastable zincblende phases being about 1 eV per formula unit higher in energy than the ground state nickel-arsenide (B8 1 ) phases. However, spintronic devices require thick films or layers. Therefore, it is important to explore theoretically other halfmetallic ferromagnetic materials, which on the one hand are compatible with the binary tetrahedral-coordinated semiconductors, and on the other hand are not only low in energy with respect to the corresponding ground-state structures but also mechanically stable against structural deformations.In this Letter we make use of an accurate fullpotential density-functional method to study systematically transition-metal chalcogenides in the zincblende and nickel-arsenide structures in order to find halfmetallic ferromagnetic phases which could be realized in the form of films and layers thick enough. We shall show that CrTe, CrSe, and VTe in the zincblende structure are excellent half-metallic ferromagnets with wide halfmetallic gaps. They will be proved to be mechanically stable and approximately 0.31-0.53 eV per formula unit higher in energy than the corresponding ground-state phases, and therefore would be grown epitax...

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Magnetic, optical, and magneto-optical properties of MnX(X=As, Sb, or Bi) from full-potential calculations

Cited by 151 publications

References 81 publications

Structure and magnetic properties of the MnBi low temperature phase

Structure and magnetic properties of the MnBi low temperature phase

Phase stability, electronic structure, and optical properties of indium oxide polytypes

Half-Metallic Ferromagnetism and Structural Stability of Zincblende Phases of the Transition-Metal Chalcogenides

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