Origin of a needle-like granular structure for ultrananocrystalline diamond films grown in a N<sub>2</sub>/CH<sub>4</sub> plasma

Sankaran, Kamatchi Jothiramalingam; Kurian, Joji; Chen, H C; Dong, Chung‐Li; Lee, C Y; Tai, Nyan‐Hwa; Lin, I‐Nan

doi:10.1088/0022-3727/45/36/365303

Cited by 101 publications

(107 citation statements)

References 80 publications

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“…3,4 Different morphologies have been achieved by variations of the gas mixture and pressure, which leads to homogenous flat films, but also clustered surfaces and also needle like diamond grains 9 are presented, resulting in total a broad difference, ranging from insulating films of σ < 10 −9 (S/cm) up to high conducting ones with a mail address corresponding author: michael.mertens@uni-ulm.de σ = 10 3 (S/cm). In contrast, nanocrystalline diamond films grown by HFCVD usually possess high electrical resistivity.…”

Section: Introductionmentioning

confidence: 99%

Structural properties of highly conductive ultra-nanocrystalline diamond films grown by hot-filament CVD

et al. 2017

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In this work we show the correlation of the electrical conductivity of ultra-nanocrystalline (UNCD) diamond films grown by hot filament chemical vapor deposition (HFCVD) with their structural properties. The substrate temperature, the methane to hydrogen ratio and the pressure are the main factor influencing the growth of conductive UNCD films, which extends from electrical resistive diamond films (<10-4 S/cm) to highly conductive diamond films with a specific conductivity of 300 S/cm. High-resolution-transmission-electron-microscopy (HRTEM) and electron-energy-loss-spectroscopy (EELS) have been done on the highly conductive diamond films, to show the origin of the high electrical conductivity. The HRTEM results show random oriented diamond grains and a large amount of nano-graphite between the diamond crystals. EELS investigations are confirming these results. Raman measurements are correlated with the specific conductivity, which shows structural changes of sp2 carbons bonds as function of conductivity. Hall experiments complete the results, which lead to a model of an electron mobility based conductivity, which is influenced by the structural properties of the grain boundary regions in the ultra-nanocrystalline diamond films.

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Section: Introductionmentioning

confidence: 99%

Structural properties of highly conductive ultra-nanocrystalline diamond films grown by hot-filament CVD

et al. 2017

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“…The existing model proposes that the alteration of the granular structure of diamond films is related closely with the presence of the C 2 and CH species in the plasma. 22,41 That the C 2 species can nucleate diamond clusters easily [7][8][9] is the main factor resulting in the formation of ultra-small grains in UNCD films. In contrast, the presence of sufficient amount of CH species in the plasma is necessary for retaining the small size of the diamond grains, 41 as the CH species can encapsulate the newly nucleated diamond clusters, thereby preventing them from growing bigger.…”

Section: Discussionmentioning

confidence: 99%

Structural modification of nanocrystalline diamond films via positive/negative bias enhanced nucleation and growth processes for improving their electron field emission properties

Saravanan

Huang

Sankaran

et al. 2015

Journal of Applied Physics

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Electron field emission (EFE) properties of nanocrystalline diamond (NCD) films synthesized by the bias-enhanced growth (beg) process under different bias voltages were investigated. The induction of the nanographitic phases is presumed to be the prime factor in enhancing the EFE properties of negative biased NCD films. Transmission electron microscopic investigations reveal that a negative bias voltage of −300 V increases the rate of growth for NCD films with the size of the grains changing from nano to ultranano size. This effect also is accompanied by the induction of nanographitic filaments in the grain boundaries of the films. The turn-on field (E0) for the EFE process then effectively gets reduced. The EFE process of the beg-NCD−300V films can be turned on at E0 = 3.86 V/μm, and the EFE current density achieved is 1.49 mA/cm2 at an applied field of 7.85 V/μm. On the other hand, though a positive-bias beg process (+200 V) results in the reduction of grain size, it does not induce sufficient nanographitic phases to lower the E0 value of the EFE process. Moreover, the optical emission spectroscopic investigation indicates that one of the primary causes that changes the granular structure of the NCD films is the increase in the proportion of C2 and CH species induced in the growing plasma. The polarity of the bias voltage is of less importance in the microstructural evolution of the films.

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“…Dosage of P-ions (10 13 800°C-annealed samples and as 16.87 V/μm for e-UNCD, which were 1 × 10 15 ions/cm 2 P-ion implanted/800°C-annealed, even though the surface resistivity of these films is markedly smaller than the other films (i.e.,σ b-UNCD = 7.05 × 10 6 , σ c-UNCD = 3.14 × 10 6 , σ d-UNCD = 5.85 × 10 4 and σ e-UCND = 2.66 × 10 3 Ω/squares). The EFE parameters are also listed in Table 1.…”

Section: Samplementioning

confidence: 92%

“…Incorporation of N 2 into the growth plasma of UNCD films gives rise to the conversion of a-C phase to graphite phase at the grain boundaries, increasing the number of conduction paths in the material and hence efficiently advancing the electrical conductivity and EFE properties of the films. [10][11][12][13] However, N 2 incorporation via the addition of N 2 gas to the growth plasma requires high growth temperature (700°C) [13]. On the other hand, ion implantation has long been utilized to amend the properties of materials through controlled doping, using select dopants [14][15][16][17].…”

Section: Introductionmentioning

confidence: 99%

The microstructural evolution of ultrananocrystalline diamond films due to P ion implantation and annealing process-dosage effect

Lin

Yeh

Dong

et al. 2015

Diamond and Related Materials

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Origin of a needle-like granular structure for ultrananocrystalline diamond films grown in a N₂/CH₄ plasma

Cited by 101 publications

References 80 publications

Structural properties of highly conductive ultra-nanocrystalline diamond films grown by hot-filament CVD

Structural properties of highly conductive ultra-nanocrystalline diamond films grown by hot-filament CVD

Structural modification of nanocrystalline diamond films via positive/negative bias enhanced nucleation and growth processes for improving their electron field emission properties

The microstructural evolution of ultrananocrystalline diamond films due to P ion implantation and annealing process-dosage effect

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Origin of a needle-like granular structure for ultrananocrystalline diamond films grown in a N2/CH4 plasma

Cited by 101 publications

References 80 publications

Structural properties of highly conductive ultra-nanocrystalline diamond films grown by hot-filament CVD

Structural properties of highly conductive ultra-nanocrystalline diamond films grown by hot-filament CVD

Structural modification of nanocrystalline diamond films via positive/negative bias enhanced nucleation and growth processes for improving their electron field emission properties

The microstructural evolution of ultrananocrystalline diamond films due to P ion implantation and annealing process-dosage effect

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Origin of a needle-like granular structure for ultrananocrystalline diamond films grown in a N₂/CH₄ plasma