Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation

Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation

© 2016 American Physical Society. We present calculations of the lattice constants, structural parameters, bulk moduli, energies of formation, and band structures of Mg-IV-N2 compounds with IV=Si, Ge, Sn by using the full-potential linearized muffin-tin orbital method and the quasiparticle-self-cons...

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Main Authors: Atchara Punya Jaroenjittichai, Walter R.L. Lambrecht
Format: Journal
Published: 2018
Subjects:
Materials Science
Physics and Astronomy
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http://cmuir.cmu.ac.th/jspui/handle/6653943832/55916
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spelling th-cmuir.6653943832-559162018-09-05T03:13:30Z Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation Atchara Punya Jaroenjittichai Walter R.L. Lambrecht Materials Science Physics and Astronomy © 2016 American Physical Society. We present calculations of the lattice constants, structural parameters, bulk moduli, energies of formation, and band structures of Mg-IV-N2 compounds with IV=Si, Ge, Sn by using the full-potential linearized muffin-tin orbital method and the quasiparticle-self-consistent GW approach for the wurtzite-based Pna21 crystal structure. The lattice parameters calculated with the generalized gradient approximation (GGA) are found to be in good agreement (within 1%) with experiment for the cases of MgSiN2 and MgGeN2, where data are available. Similar to the Zn-IV-N2 compounds, MgSiN2 is found to have an indirect gap slightly lower than the lowest direct gap, while the other materials have direct gaps. The direct gaps, calculated at the GGA lattice constant, range from 3.43 eV for MgSnN2 to 5.14 eV for MgGeN2 and 6.28 eV for MgSiN2 in the 0.8Σ approximation, i.e., reducing the QSGWΣ by a factor 0.8 and including an estimated zero-point-motion correction. The symmetry character of the valence-band maximum states and their splittings and effective masses are determined. The conduction-band minima are found to have slightly higher Mg s- than Si s-like character in MgSiN2 but in MgGeN2 and MgSnN2, the group-IV-s character becomes increasingly dominant. 2018-09-05T03:04:34Z 2018-09-05T03:04:34Z 2016-09-09 Journal 24699969 24699950 2-s2.0-84991257231 10.1103/PhysRevB.94.125201 https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84991257231&origin=inward http://cmuir.cmu.ac.th/jspui/handle/6653943832/55916
institution Chiang Mai University
building Chiang Mai University Library
country Thailand
collection CMU Intellectual Repository
topic Materials Science
Physics and Astronomy
spellingShingle Materials Science
Physics and Astronomy
Atchara Punya Jaroenjittichai
Walter R.L. Lambrecht
Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation
description © 2016 American Physical Society. We present calculations of the lattice constants, structural parameters, bulk moduli, energies of formation, and band structures of Mg-IV-N2 compounds with IV=Si, Ge, Sn by using the full-potential linearized muffin-tin orbital method and the quasiparticle-self-consistent GW approach for the wurtzite-based Pna21 crystal structure. The lattice parameters calculated with the generalized gradient approximation (GGA) are found to be in good agreement (within 1%) with experiment for the cases of MgSiN2 and MgGeN2, where data are available. Similar to the Zn-IV-N2 compounds, MgSiN2 is found to have an indirect gap slightly lower than the lowest direct gap, while the other materials have direct gaps. The direct gaps, calculated at the GGA lattice constant, range from 3.43 eV for MgSnN2 to 5.14 eV for MgGeN2 and 6.28 eV for MgSiN2 in the 0.8Σ approximation, i.e., reducing the QSGWΣ by a factor 0.8 and including an estimated zero-point-motion correction. The symmetry character of the valence-band maximum states and their splittings and effective masses are determined. The conduction-band minima are found to have slightly higher Mg s- than Si s-like character in MgSiN2 but in MgGeN2 and MgSnN2, the group-IV-s character becomes increasingly dominant.
format Journal
author Atchara Punya Jaroenjittichai
Walter R.L. Lambrecht
author_facet Atchara Punya Jaroenjittichai
Walter R.L. Lambrecht
author_sort Atchara Punya Jaroenjittichai
title Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation
title_short Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation
title_full Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation
title_fullStr Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation
title_full_unstemmed Electronic band structure of Mg-IV- N2 compounds in the quasiparticle-self-consistent GW approximation
title_sort electronic band structure of mg-iv- n2 compounds in the quasiparticle-self-consistent gw approximation
publishDate 2018
url https://www.scopus.com/inward/record.uri?partnerID=HzOxMe3b&scp=84991257231&origin=inward
http://cmuir.cmu.ac.th/jspui/handle/6653943832/55916
_version_ 1681424594653675520

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