Point Defects in a Two-Dimensional ZnSnN2 Nanosheet: A First-Principles Study on the Electronic and Magnetic Properties

Research output: Contribution to journalArticleResearchpeer review

Authors

  • Asadollah Bafekry
  • Mehrdad Faraji
  • Mohamed M. Fadlallah
  • Bohayra Mortazavi
  • A. Abdolahzadeh Ziabari
  • A. Bagheri Khatibani
  • Chuong V. Nguyen
  • Mitra Ghergherehchi
  • Daniela Gogova

Research Organisations

External Research Organisations

  • Shahid Beheshti University
  • University of Antwerp (UAntwerpen)
  • TOBB University of Economics and Technology
  • Banha University
  • Islamic Azad University
  • Le Quy Don Technical University
  • Sungkyunkwan University
  • University of Oslo
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Details

Original languageEnglish
Pages (from-to)13067-13075
Number of pages9
JournalJournal of Physical Chemistry C
Volume125
Issue number23
Early online date3 Jun 2021
Publication statusPublished - 17 Jun 2021

Abstract

The reduction of dimensionality is a very effective way to achieve appealing properties in two-dimensional materials (2DMs). First-principles calculations can greatly facilitate the prediction of 2DM properties and find possible approaches to enhance their performance. We employed first-principles calculations to gain insight into the impact of different types of point defects (vacancies and substitutional dopants) on the electronic and magnetic properties of a ZnSnN2 (ZSN) monolayer. We show that Zn, Sn, and N + Zn vacancy-defected structures are p-type conducting, while the defected ZSN with a N vacancy is n-type conducting. For substitutional dopants, we found that all doped structures are thermally and energetically stable. The most stable structure is found to be B-doping at the Zn site. The highest work function value (5.0 eV) has been obtained for Be substitution at the Sn site. Li-doping (at the Zn site) and Be-doping (at the Sn site) are p-type conducting, while B-doping (at the Zn site) is n-type conducting. We found that the considered ZSN monolayer-based structures with point defects are magnetic, except those with the N vacancy defects and Be-doped structures. The ab initio molecular dynamics simulations confirm that all substitutionally doped and defected structures are thermally stable. Thus, our results highlight the possibility of tuning the magnetism in ZnSnN2 monolayers through defect engineering.

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Cite this

Point Defects in a Two-Dimensional ZnSnN2 Nanosheet: A First-Principles Study on the Electronic and Magnetic Properties. / Bafekry, Asadollah; Faraji, Mehrdad; Fadlallah, Mohamed M. et al.
In: Journal of Physical Chemistry C, Vol. 125, No. 23, 17.06.2021, p. 13067-13075.

Research output: Contribution to journalArticleResearchpeer review

Bafekry, A, Faraji, M, Fadlallah, MM, Mortazavi, B, Ziabari, AA, Khatibani, AB, Nguyen, CV, Ghergherehchi, M & Gogova, D 2021, 'Point Defects in a Two-Dimensional ZnSnN2 Nanosheet: A First-Principles Study on the Electronic and Magnetic Properties', Journal of Physical Chemistry C, vol. 125, no. 23, pp. 13067-13075. https://doi.org/10.1021/acs.jpcc.1c03749
Bafekry, A., Faraji, M., Fadlallah, M. M., Mortazavi, B., Ziabari, A. A., Khatibani, A. B., Nguyen, C. V., Ghergherehchi, M., & Gogova, D. (2021). Point Defects in a Two-Dimensional ZnSnN2 Nanosheet: A First-Principles Study on the Electronic and Magnetic Properties. Journal of Physical Chemistry C, 125(23), 13067-13075. https://doi.org/10.1021/acs.jpcc.1c03749
Bafekry A, Faraji M, Fadlallah MM, Mortazavi B, Ziabari AA, Khatibani AB et al. Point Defects in a Two-Dimensional ZnSnN2 Nanosheet: A First-Principles Study on the Electronic and Magnetic Properties. Journal of Physical Chemistry C. 2021 Jun 17;125(23):13067-13075. Epub 2021 Jun 3. doi: 10.1021/acs.jpcc.1c03749
Bafekry, Asadollah ; Faraji, Mehrdad ; Fadlallah, Mohamed M. et al. / Point Defects in a Two-Dimensional ZnSnN2 Nanosheet : A First-Principles Study on the Electronic and Magnetic Properties. In: Journal of Physical Chemistry C. 2021 ; Vol. 125, No. 23. pp. 13067-13075.
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abstract = "The reduction of dimensionality is a very effective way to achieve appealing properties in two-dimensional materials (2DMs). First-principles calculations can greatly facilitate the prediction of 2DM properties and find possible approaches to enhance their performance. We employed first-principles calculations to gain insight into the impact of different types of point defects (vacancies and substitutional dopants) on the electronic and magnetic properties of a ZnSnN2 (ZSN) monolayer. We show that Zn, Sn, and N + Zn vacancy-defected structures are p-type conducting, while the defected ZSN with a N vacancy is n-type conducting. For substitutional dopants, we found that all doped structures are thermally and energetically stable. The most stable structure is found to be B-doping at the Zn site. The highest work function value (5.0 eV) has been obtained for Be substitution at the Sn site. Li-doping (at the Zn site) and Be-doping (at the Sn site) are p-type conducting, while B-doping (at the Zn site) is n-type conducting. We found that the considered ZSN monolayer-based structures with point defects are magnetic, except those with the N vacancy defects and Be-doped structures. The ab initio molecular dynamics simulations confirm that all substitutionally doped and defected structures are thermally stable. Thus, our results highlight the possibility of tuning the magnetism in ZnSnN2 monolayers through defect engineering.",
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T2 - A First-Principles Study on the Electronic and Magnetic Properties

AU - Bafekry, Asadollah

AU - Faraji, Mehrdad

AU - Fadlallah, Mohamed M.

AU - Mortazavi, Bohayra

AU - Ziabari, A. Abdolahzadeh

AU - Khatibani, A. Bagheri

AU - Nguyen, Chuong V.

AU - Ghergherehchi, Mitra

AU - Gogova, Daniela

N1 - Funding Information: This work was supported by the National Research Foundation of Korea Grant funded by the Korean government (MSIT) (NRF-2015M2B2A4033123). B.M. appreciates the funding by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany’s Excellence Strategy within the Cluster of Excellence PhoenixD (EXC 2122, Project ID 390833453).

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