Atsuhito Sawabe scite author profile

Epitaxial growth of diamond on iridium thin films was performed by direct-current plasma chemical vapor deposition with ion irradiation pretreatment of the substrate. Pyramidal epitaxial diamond particles with a number density of ∼108 cm-2 were grown on the iridium film. The epitaxial relation is written as (100) diamond//(100) iridium and [001] diamond//[001] iridium. Tilting of the epitaxial relation, as occasionally observed for diamond on silicon or beta silicon carbide, is scarcely observed. Erosion,as observed for diamond on nickel substrates, is not observed. The effect of the ion irradiation of the substrate is discussed briefly.

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Growth and characterization of phosphorus doped n-type diamond thin films

Koizumi

Kamo

Sato

et al. 1998

Diamond and Related Materials

134

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Growth of diamond thin films by dc plasma chemical vapor deposition

et al. 1987

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Diamond thin films have been formed by dc plasma chemical vapor deposition with a high growth rate (∼20 μm/h). The diamond has been grown from methane (CH4) and hydrogen (H2) mixed gases on Si and α-Al2O3 substrates at a pressure of 200 Torr without surface scratching by diamond or c-BN powder. The obtained films have good crystallinity in the sense of electron and x-ray diffraction. Vicker’s hardness of the film is the same as that of natural diamond (∼10 000 kg/mm2). The influence of the dc discharge in a low vacuum (∼200 Torr) on diamond synthesis will be discussed briefly.

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Metal-insulator-vacuum type electron emission from N-containing chemical vapor deposited diamond

Okano

Yamada

Sawabe

et al. 2001

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This letter presents a clear explanation of the electron emission mechanism of the high-resistivity N-doped diamond cathode. Due to the very low barrier to emission of electrons from the N-doped diamond conduction band into vacuum, electrons in the conduction band of diamond can establish an appreciable leakage current at very low anode voltage. When such a current starts to flow, there is a field which is developed across the diamond bulk. This field is observed as an increase in the electric field at the back contact, causing the injected tunneling current increases exponentially. This process leads to the low threshold emission from the high resistivity N-doped diamond cathode.

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Atsuhito Sawabe

‘Nano-rods’ of single crystalline diamond

Epitaxial Growth of Diamond on Iridium

Growth and characterization of phosphorus doped n-type diamond thin films

Growth of diamond thin films by dc plasma chemical vapor deposition

Metal-insulator-vacuum type electron emission from N-containing chemical vapor deposited diamond

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