A. V. Logosha scite author profile

Ab initio band structure calculations are carried out for the higher borides MB 6 and MB 12 . Highprecision measurements of the elastic constants are performed for the compounds ZrB 12 , HoB 12 , ErB 12 , TmB 12 , LuB 12 , YB 6 and LaB 6 at low temperatures. The bulk properties of the borides are analyzed on the basis of the calculated equations of states and balanced crystal orbital overlap populations. Our calculations indicate that hexaborides with divalent metals, CaB 6 , SrB 6 , BaB 6 , and YbB 6 , are semiconductors with small energy gaps. The metallic MB 6 hexaborides with trivalent M atoms are found to possess larger bulk moduli values. For dodecaborides the bulk moduli are found to be higher for MB 12 with increased filling of the conduction band ͑ZrB 12 , HfB 12 , UB 12 ͒ in comparison with M 3+ B 12 compounds. The total energy calculations for different magnetic configurations in YbB 12 point to the possibility of antiferromagnetic coupling between Yb 3+ ions.

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Electronic structure, bulk and magnetic properties of MB6 and MB12 borides

Baranovskiy

Grechnev

Fil

et al. 2007

Journal of Alloys and Compounds

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Electronic structure and magnetic properties of transition metal diborides

Grechnev

Fedorchenko

Logosha

et al. 2009

Journal of Alloys and Compounds

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Anisotropy of the magnetic properties and the electronic structure of transition-metal diborides

Fedorchenko

Grechnev

Панфилов

et al. 2009

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The temperature dependences of the magnetic susceptibility χ and its anisotropy Δχ=χ∥−χ⊥ have been measured for hexagonal single crystals of transition-metal diborides MB2 (M=Sc,Ti,V,Zr,Hf) in the temperature interval 4.2–300K. It is found that the anisotropy Δχ is weakly temperature-dependent, a nonmonotonic function of the filling of the hybridized p−d conduction band, and largest for group-IV transition metals. First-principles calculations of the electronic structure of diborides and the values of the paramagnetic contributions (spin and Van Vleck) to their susceptibility show that the behavior of the magnetic anisotropy is due to the competition between Van Vleck paramagnetism and orbital diamagnetism of the conduction electrons.

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A. V. Logosha

Electronic structure and bulk properties of MB6 and MB12 borides

Electronic structure, bulk and magnetic properties of MB6 and MB12 borides

Electronic structure and magnetic properties of transition metal diborides

Anisotropy of the magnetic properties and the electronic structure of transition-metal diborides

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