H. H. Farrell scite author profile

H. H. Farrell

5Publications

192Citation Statements Received

11Citation Statements Given

How they've been cited

415

187

How they cite others

Affiliations

Idaho National Laboratory, Core Competence, Brookhaven National Laboratory

Publications

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Molecular-beam epitaxy growth mechanisms on GaAs(100) surfaces

Farrell¹

1987

182

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A significant liability in the use of molecular-beam epitaxy (MBE) to grow device grade compound semiconductor materials is the cost entailed by the necessity of using ultrahigh vacuum and high-growth temperatures. The commercial feasibility of this process could be considerably enhanced if growth temperatures could be cut by one-half or more, In addition, lower growth temperatures could make feasible the growth of semiconductor layers by MBE on top of previously processed structures without degrading or destroying those structures from the high temperatures currently needed for semiconductor growth, An understanding of the detailed atomic nature of this growth process would be valuable in tailoring existing, or developing new techniques towards this end. In the previous papers in this series, we have developed atomic models for various structures on the GaAs( 100) (and related) surfaces used in MBE growth, In this paper, we combine those models to suggest an actual mechanism whereby molecular-beam epitaxy occurs. This proposed mechanism is highly suggestive in terms of improving growth techniques by, for example, varying the incident flux of the constituent species or by using monochromatic light during the growth process. It is foreseen that the implementation of such variations at specific points during the growth cycle may allow substantial reduction in substrate temperature or otherwise improve MBE growth on compound-semiconductor surfaces.

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Binding energy, vapor pressure, and melting point of semiconductor nanoparticles

Farrell

Siclen

2007

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Catalytic activity of supported metal particles for sulfuric acid decomposition reaction

et al. 2009

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The structure of the ZnSe(100)c(2×2) surface

Farrell¹

1990

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Grain-boundary diffusion in thin films. II. Multiple grain boundaries and surface diffusion

Gilmer¹,

Farrell²

1976

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Diffusion in polycrystalline thin films is investigated using both analytical and numerical methods. Bulk, grain-boundary, and interfacial diffusion are all included in the analysis, and the conditions under which each process influences the concentration profile are evaluated. The thin film is treated as a slab of finite thickness containing uniformly spaced grain boundaries that are perpendicular to the plane of the film. One surface of the slab is assumed to be in contact with an infinite reservoir of the diffusing species. Three limiting cases are considered in which the second surface is (i) a barrier to diffusion, (ii) a plane with an infinite surface diffusion coefficient, and (iii) a zero-concentration surface.

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H. H. Farrell

Molecular-beam epitaxy growth mechanisms on GaAs(100) surfaces

Binding energy, vapor pressure, and melting point of semiconductor nanoparticles

Catalytic activity of supported metal particles for sulfuric acid decomposition reaction

The structure of the ZnSe(100)c(2×2) surface

Grain-boundary diffusion in thin films. II. Multiple grain boundaries and surface diffusion

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