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Mechanism for diamond growth from methyl radicals
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TLDR
In this paper, the authors used a 9-carbon model compound to describe a proposed mechanism for homoepitaxial growth of diamond from methyl radicals on a hydrogenated, electrically neutral (100) surface.Abstract:
We use a 9‐carbon model compound to describe a proposed mechanism for homoepitaxial growth of diamond from methyl radicals on a hydrogenated, electrically neutral (100) surface. We estimate enthalpy and entropy changes for each step in the mechanism using group additivity methods, taking into account the types of bonding and steric repulsions found on the (100) surface. Rate constants are estimated based on analogous reactions for hydrocarbon molecules, while gas phase species concentrations are taken from our previous measurements. The rate equations are then integrated. The method, which contains no adjustable parameters or phenomenological constants, predicts a growth rate of between 0.06 and 0.6 μm/h, depending on the local details of the surface. Uncertainties related to the use of a model compound rather than diamond are discussed. The analysis demonstrates that the proposed mechanism is feasible.read more
Citations
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Formation of nascent soot and other condensed-phase materials in flames
TL;DR: A review of the current state of knowledge of the fundamental sooting processes, including the chemistry of soot precursors, particle nucleation and mass/size growth, can be found in this article.
Journal ArticleDOI
Towards a general concept of diamond chemical vapour deposition
TL;DR: In this paper, a C H O phase diagram is introduced providing a common scheme for all major diamond chemical vapour deposition (CVD) methods used to date, revealing that low pressure diamond synthesis is only feasible within a well-defined field of the phase diagram, a diamond domain that allows general predictions of gas phase compositions and starting materials suitable for diamond synthesis.
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Thin film diamond growth mechanisms. Comment
TL;DR: In this paper, the principal chemical mechanisms relevant to the growth of diamond from gaseous hydrogen and hydrocarbon species are presented, with a detailed model of growth at the (110) surface sites from single carbon reactants.
Journal ArticleDOI
Understanding the chemical vapor deposition of diamond: recent progress.
TL;DR: Experimental measurements in situ to diamond CVD reactors, and MPCVD in particular, coupled with models of the gas phase chemical and plasma kinetics to provide insight into the distribution of critical chemical species throughout the reactor are reviewed.
Journal ArticleDOI
CVD diamond films: nucleation and growth
TL;DR: In this article, a review of low-pressure growth methods of diamond films is presented, focusing on recent advances in the understanding of the mechanism of diamond nucleation and metastable growth, which raises hope that single crystalline diamond films are not far beyond reach.
References
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Journal ArticleDOI
Low-Pressure, Metastable Growth of Diamond and "Diamondlike" Phases
John C. Angus,Cliff C. Hayman +1 more
TL;DR: Vapor-grown diamond and diamondlike materials may have eventual applications in abrasives, tool coatings, bearing surfaces, electronics, optics, tribological surfaces, and corrosion protection.
Journal ArticleDOI
Epitaxial growth mechanism of diamond crystal in methane-hydrogen plasma.
TL;DR: A most probable mechanism of the epitaxial growth of diamond crystal, which was elucidated by the method of quantum chemical calculations, is found to proceed in two steps.
Journal ArticleDOI
Measurement of stable species present during filament‐assisted diamond growth
TL;DR: In this article, Mole fractions of two major stable species at the surface of a silicon substrate were measured during diamond growth as a function of the filament-to-substrate distance.
Journal ArticleDOI
Methyl radical and H-atom concentrations during diamond growth
TL;DR: In this paper, the gas phase composition at the surface of a growing diamond film was measured as a function of the initial methane (CH4) fraction and, for a 2% methane fraction, added oxygen (O2).
Journal ArticleDOI
The Importance of the Positively Charged Surface for the Epitaxial Growth of Diamonds at Low Pressure
TL;DR: The mechanism of the propagation of the epitaxial growth of diamonds at low pressure was investigated in terms of quantum chemistry in this article, where the most important requirement is the maintaining of positive charges on the growing surface.
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