CCl radicals as a carbon source for diamond thin film deposition

Qi An; Mu Jeng Cheng; William A. Goddard; Andres Jaramillo-Botero

doi:10.1021/jz402527y

CCl radicals as a carbon source for diamond thin film deposition

Qi An, Mu Jeng Cheng, William A. Goddard, Andres Jaramillo-Botero

California Institute of Technology

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6 Citas (Scopus)

Resumen

We use first-principles quantum mechanical calculations to study diamond thin film growth on the (100) surface using CCl radicals as the carbon source. Our results show that CCl inserts into the surface dimer C-C bonds with a barrier of 10.5 kcal/mol, roughly half of the energy required for traditional CH₂ insertion (22.0 kcal/mol). In addition to this, CCl has improved surface mobility (∼30.0 kcal/mol barrier, versus 35 kcal/mol for CH ₂, along the C-C dimer chain direction), and hydrogen abstraction from the surface is also favored via atomic Cl in the vapor phase. These results explain the lower substrate temperatures achieved in crystal diamond growth from the use of chlorinated sources in CVD processes, as opposed to the more traditional CH₄/H₂ derived species. Our results also suggest that further reductions in substrate temperatures are possible from using CCl as the only carbon source.

Idioma original	Inglés
Páginas (desde-hasta)	481-484
Número de páginas	4
Publicación	Journal of Physical Chemistry Letters
Volumen	5
N.º	3
DOI	https://doi.org/10.1021/jz402527y
Estado	Publicada - 06 feb. 2014
Publicado de forma externa	Sí

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title = "CCl radicals as a carbon source for diamond thin film deposition",

abstract = "We use first-principles quantum mechanical calculations to study diamond thin film growth on the (100) surface using CCl radicals as the carbon source. Our results show that CCl inserts into the surface dimer C-C bonds with a barrier of 10.5 kcal/mol, roughly half of the energy required for traditional CH2 insertion (22.0 kcal/mol). In addition to this, CCl has improved surface mobility (∼30.0 kcal/mol barrier, versus 35 kcal/mol for CH 2, along the C-C dimer chain direction), and hydrogen abstraction from the surface is also favored via atomic Cl in the vapor phase. These results explain the lower substrate temperatures achieved in crystal diamond growth from the use of chlorinated sources in CVD processes, as opposed to the more traditional CH4/H2 derived species. Our results also suggest that further reductions in substrate temperatures are possible from using CCl as the only carbon source.",

keywords = "CVD diamond deposition, chlorinated precursors, low-temperature diamond growth",

author = "Qi An and Cheng, {Mu Jeng} and Goddard, {William A.} and Andres Jaramillo-Botero",

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AU - An, Qi

AU - Cheng, Mu Jeng

AU - Goddard, William A.

AU - Jaramillo-Botero, Andres

PY - 2014/2/6

Y1 - 2014/2/6

N2 - We use first-principles quantum mechanical calculations to study diamond thin film growth on the (100) surface using CCl radicals as the carbon source. Our results show that CCl inserts into the surface dimer C-C bonds with a barrier of 10.5 kcal/mol, roughly half of the energy required for traditional CH2 insertion (22.0 kcal/mol). In addition to this, CCl has improved surface mobility (∼30.0 kcal/mol barrier, versus 35 kcal/mol for CH 2, along the C-C dimer chain direction), and hydrogen abstraction from the surface is also favored via atomic Cl in the vapor phase. These results explain the lower substrate temperatures achieved in crystal diamond growth from the use of chlorinated sources in CVD processes, as opposed to the more traditional CH4/H2 derived species. Our results also suggest that further reductions in substrate temperatures are possible from using CCl as the only carbon source.

AB - We use first-principles quantum mechanical calculations to study diamond thin film growth on the (100) surface using CCl radicals as the carbon source. Our results show that CCl inserts into the surface dimer C-C bonds with a barrier of 10.5 kcal/mol, roughly half of the energy required for traditional CH2 insertion (22.0 kcal/mol). In addition to this, CCl has improved surface mobility (∼30.0 kcal/mol barrier, versus 35 kcal/mol for CH 2, along the C-C dimer chain direction), and hydrogen abstraction from the surface is also favored via atomic Cl in the vapor phase. These results explain the lower substrate temperatures achieved in crystal diamond growth from the use of chlorinated sources in CVD processes, as opposed to the more traditional CH4/H2 derived species. Our results also suggest that further reductions in substrate temperatures are possible from using CCl as the only carbon source.

KW - CVD diamond deposition

KW - chlorinated precursors

KW - low-temperature diamond growth

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CCl radicals as a carbon source for diamond thin film deposition

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