2003
DOI: 10.1063/1.1603951
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Hydrogen content and density in nanocrystalline carbon films of a predominant diamond character

Abstract: Nanocrystalline carbon films possessing a prevailing diamond or graphite character, depending on substrate temperature, can be deposited from a methane hydrogen mixture by the direct current glow discharge plasma chemical vapor deposition method. While at a temperature of ∼880 °C, following the formation of a thin precursor graphitic film, diamond nucleation occurs and a nanodiamond film grows, at higher and lower deposition temperatures the films maintain their graphitic character. In this study the hydrogen … Show more

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Cited by 27 publications
(15 citation statements)
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“…The hydrogen concentration depth profile of the dc GD film re- flects the evolution of its structure from an initial low density, low hydrogen concentration graphitic film through a medium density, hydrogen containing film until a dense, hydrogen containing matrix evolves, in which ~5 nm sized nano-diamond crystallites precipitate. Our previous measurements of absolute hydrogen concentration within these films by means of ERDA revealed hydrogen concentration of 15-20 at% [12] which confirms the present SIMS measurements.…”
supporting
confidence: 79%
See 1 more Smart Citation
“…The hydrogen concentration depth profile of the dc GD film re- flects the evolution of its structure from an initial low density, low hydrogen concentration graphitic film through a medium density, hydrogen containing film until a dense, hydrogen containing matrix evolves, in which ~5 nm sized nano-diamond crystallites precipitate. Our previous measurements of absolute hydrogen concentration within these films by means of ERDA revealed hydrogen concentration of 15-20 at% [12] which confirms the present SIMS measurements.…”
supporting
confidence: 79%
“…In our previous works [9,10] we showed that the growth of the dc GD CVD film advances through the following stages: (1) graphitic film with its basal plane perpendicular to the substrate, a low H concentration and low (~2.2 g/cm 3 ) density, (2) an increase of the density followed by incorporation of hydrogen, (3) the formation of a dense (~3 g/cm 3 ), hydrogen rich layer in which diamond nucleates and grows. The hydrogen concentration in the nano-diamond film deposited by dc GD CVD increases from 3.3 × 10 21 at the nanographitic precursor region to 1.45 × 10 22 atoms/cm 3 in the ~5 nm sized nano-diamond crystallites region [12]. The hydrogen concentration depth profile of the dc GD film re- flects the evolution of its structure from an initial low density, low hydrogen concentration graphitic film through a medium density, hydrogen containing film until a dense, hydrogen containing matrix evolves, in which ~5 nm sized nano-diamond crystallites precipitate.…”
mentioning
confidence: 99%
“…28 The hydrogen concentration depth profile of the dc GD film reflects the evolution of its structure from an initial low density, low hydrogen concentration graphitic film through a medium density, hydrogen containing film until a dense, hydrogen containing matrix evolves, in which ϳ5 nm sized nanodiamond crystallites precipitate. Our previous measurements of absolute hydrogen concentration within these films by means of ERDA revealed hydrogen concentration of 15-20 at.…”
Section: Resultsmentioning
confidence: 99%
“…21 While hydrogen incorporation and effects in hydrogenated amorphous carbon films, which may contain up to 45 at % hydrogen, 22 are relatively well studied, [22][23][24][25][26][27] only little information is available on hydrogen distribution, concentration, and location in diamond films. 21,[28][29][30][31] Fourier transform infrared absorption and elastic recoil detection analysis ͑ERDA͒ were used to evaluate the location of hydrogen in diamond. It has been found that the hydrogen in CVD diamond is incorporated in both grain boundaries [19][20][21]30 ͓on diamond surfaces and in nondiamond ͑graphitic and amorphous carbon͒ regions͔ and also is trapped in grain defects.…”
Section: Introductionmentioning
confidence: 99%
“…The well-known negative electron affinity and high conductivity of diamond surfaces are properties of fully hydrogenated diamond surfaces [5][6][7]. Hydrogen is said to be distributed nonhomogeneously in diamond films and it is likely to be found on the surface, at grain boundaries and dislocations or simply as lattice defects [8][9][10][11].…”
Section: Introductionmentioning
confidence: 99%