Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
1794559 | Journal of Crystal Growth | 2008 | 17 Pages |
Abstract
Our model, applicable to the growth of any cubic lattice material, establishes a complete mapping of the final morphology state of growing diamond, as a function of the growth rates of the crystalline planes considered, namely {1Â 0Â 0}, {1Â 1Â 1}, {1Â 1Â 0}, and {1Â 1Â 3} planes, all of which have been observed experimentally in diamond films. The model makes no claim as to the stability of the obtained faces, such as the occurrence of non-epitaxial crystallites or twinning. It is also possible to deduce transient behavior of the crystal morphology as growth time is increased. The model conclusions are presented in the form of a series of diagrams, which trace the existence (and dominance) boundaries of each face type, in presence of the others, and where each boundary crossing represent a topology change in terms of number of faces, edges and vertices. We validate the model by matching it against crystals published in the literature and illustrate its predictive value by suggesting ways to increase usable surface area of the diamond film.
Keywords
Related Topics
Physical Sciences and Engineering
Physics and Astronomy
Condensed Matter Physics
Authors
F. Silva, X. Bonnin, J. Achard, O. Brinza, A. Michau, A. Gicquel,