Exploring new insights in BAlN from evolutionary algorithms ab initio computations

•Combination of density functional theory and evolutionary structure predictions is used here.•Thermodynamic, mechanical, dynamical and optical properties of BxAl1−xN alloys are studied.•Cubic BAl3N4, and B3AlN4; and tetragonal BAlN2 have been predicted.•We show that these structures are mechanicall...

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Bibliographic Details
Published in:Physics letters. A 2019-04, Vol.383 (13), p.1385-1388
Main Authors: Maiz Hadj Ahmed, H., Benaissa, H., Zaoui, A., Ferhat, M.
Format: Article
Language:English
Subjects:
[formula omitted] alloys
Civil Engineering
Density functional theory (DFT)
Engineering Sciences
Evolutionary algorithm
Mechanical, dynamical and optical properties
Optical band gap bowing parameter
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Summary:•Combination of density functional theory and evolutionary structure predictions is used here.•Thermodynamic, mechanical, dynamical and optical properties of BxAl1−xN alloys are studied.•Cubic BAl3N4, and B3AlN4; and tetragonal BAlN2 have been predicted.•We show that these structures are mechanically and dynamically stable.•Direct band gap of BN-AlN evinces strong deviation from linear dependence on B composition. BN-AlN alloys are potential candidates to achieve wide band gap material for ultraviolet device applications. By combing density functional theory and evolutionary structure predictions, we systematically explore the thermodynamic, mechanical, dynamical and optical properties of BxAl1−xN alloys. Through structure search, three compounds (cubic (BAl3N4, and B3AlN4, space group P-43m), and tetragonal (BAlN2, space group P-42m)) have been predicted. The calculated relative large formation enthalpies suggest that large miscibility gap exists in BAlN alloys. In addition, computed elastic constants and phonon show that these structures are mechanically and dynamically stable. From the state of the art LDA-1/2 we show that the direct band gap of BN-AlN evinces strong deviation from a linear dependence on B composition. We found -in particular- giant direct band gap bowing parameter of b∼11.6 eV for the entire range of composition, where b parameter is found to be sensitive to composition x. From a detailed analysis of the physical origin of the optical gap bowing b, we found that structural and chemical contributions play the most significant effects behind the huge optical band gap bowing parameter of BAlN alloys.
ISSN:0375-9601
1873-2429
DOI:10.1016/j.physleta.2019.02.010