Control of Competing Thermodynamics and Kinetics in Vapor Phase Thin-Film Growth of Nitrides and Borides

  1. Ohkubo, Isao
  2. Aizawa, Takashi
  3. Nakamura, Katsumitsu
  4. Mori, Takao

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WeightNameValue
1000 Titel
  • Control of Competing Thermodynamics and Kinetics in Vapor Phase Thin-Film Growth of Nitrides and Borides
1000 Autor/in
  1. Ohkubo, Isao |
  2. Aizawa, Takashi |
  3. Nakamura, Katsumitsu |
  4. Mori, Takao |
1000 Verlag
  • Frontiers Media S.A.
1000 Erscheinungsjahr 2021
1000 Publikationstyp
  1. Artikel |
1000 Online veröffentlicht
  • 2021-07-27
1000 Erschienen in
1000 Quellenangabe
  • 9:642388
1000 Copyrightjahr
  • 2021
1000 Embargo
  • 2022-01-29
1000 Lizenz
1000 Verlagsversion
  • https://doi.org/10.3389/fchem.2021.642388 |
  • https://www.ncbi.nlm.nih.gov/pmc/articles/PMC8353106/ |
1000 Publikationsstatus
1000 Begutachtungsstatus
1000 Abstract/Summary
  • <jats:p>Thin-film  growth is a platform technique that allows the preparation of various undeveloped materials and enables the development of novel energy generation devices. Preferred phase formation, control of crystalline orientation and quality, defect concentration, and stoichiometry in thin films are important for obtaining thin films exhibiting desired physical and chemical properties. In particular, the control of crystalline phase formation by utilizing thin-film technology favors the preparation of undeveloped materials. In this study, thin-film growth of transition metal nitride and rare-earth metal boride was performed using remote plasma–assisted molecular beam epitaxy and hybrid physical–chemical vapor deposition techniques, and was successfully achieved by tuning the competition between thermodynamics and kinetics during vapor-phase thin-film growth. Growth conditions of high crystalline quality titanium nitride thin films and high phase purity ytterbium boride thin films were not thermodynamically favorable. Appropriate control of the contribution degree of thermodynamics and kinetics during vapor-phase thin-film growth is crucial for fabricating high phase purity and high crystalline quality thin films.</jats:p>
1000 Sacherschließung
lokal chemical vapor deposition
lokal nitrides
lokal molecular beam epitaxy
lokal borides
lokal thin-film growth
lokal Chemistry
1000 Liste der Beteiligten
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1000 Hinweis
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  1. Japan Science and Technology Agency |
  2. Japan Society for the Promotion of Science |
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1000 Dateien
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    1000 Förderer Japan Science and Technology Agency |
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    1000 Fördernummer -
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    1000 Förderer Japan Society for the Promotion of Science |
    1000 Förderprogramm -
    1000 Fördernummer -
1000 Objektart article
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1000 @id frl:6479730.rdf
1000 Erstellt am 2024-05-21T23:38:39.626+0200
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1000 Zuletzt bearbeitet 2024-05-22T14:28:32.658+0200
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