Qualitative analysis of a diamondlike carbon film by angle-resolved x-ray photoelectron spectroscopy

a Oxygen-related surface functional groups on diamond-like carbon (DLC) films were derivatized with fluorine-and nitrogenrelated groups by the gas-phase chemical derivatization (GCD) method, and the groups were analyzed quantitatively by X-ray photoelectron spectroscopy (XPS). It is desirable that a derivatization reaction is unique to the target group; however, it usually causes undesirable side reactions which affect other groups. This diversity of the reactions has complicated the analysis. In this report, we have overcome the problem by applying a mathematical treatment which takes the side reactions into account. This improved analysis shows that it is no longer necessary to have derivatization reactions unique to the target groups. As a result, it is demonstrated that the carbonyl (C O) group is the dominant surface functional group on both the DLC and its wet-oxidized films, the carboxyl (COOH) group plays a minor role, and the presence of the hydroxyl (OH) group is logically denied. Considering the oxidation steps of these oxygen-related surface functional groups, it is suggested that the C O group on the DLC films requires the cleavage of the carbon-carbon bond with a relatively high activation energy barrier to change into the COOH group.

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“…[13,15] The carbon source was 30 sccm of benzene gas, the DC bias voltage applied to the substrate was −2 kV, and the temperature was 180…”

Section: Methodsmentioning

confidence: 99%

X‐ray photoelectron analysis of surface functional groups on diamond‐like carbon films by gas‐phase chemical derivatization method

Takabayashi

Okamoto

Motoyama

et al. 2010

Surface & Interface Analysis

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“…8,[23][24][25][26] The deposition conditions were as follows: the carbon source was 30 SCCM ͑SCCM denotes cubic centimeter per minute at STP͒ of benzene gas. 8,[23][24][25][26] The deposition conditions were as follows: the carbon source was 30 SCCM ͑SCCM denotes cubic centimeter per minute at STP͒ of benzene gas.…”

Section: Methodsmentioning

confidence: 99%

“…[3][4][5] X-ray photoelectron spectroscopy ͑XPS͒ provides important information on the surface chemical structures of materials as the shifts of the binding energy ͑E B ͒. 8 Hydrogen in DLC plays an important role: hydrogencarbon ͑H-C͒ bonds in DLC produce large free spaces in the structure, which inhibit conductive routes and lead to high electrical resistivity. Clues to decompose the spectrum can be obtained by systematically comparing the spectral features taken under different conditions.…”

Section: Introductionmentioning

confidence: 99%

Annealing effect on the chemical structure of diamondlike carbon

Takabayashi

Okamoto

Sakaue

et al. 2008

Journal of Applied Physics

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Electron cyclotron resonance deposition, structure, and properties of oxygen incorporated hydrogenated diamondlike amorphous carbon films J. Appl. Phys. 96, 5456 (2004); 10.1063/1.1804624Effects of thermal annealing on the structural, mechanical, and tribological properties of hard fluorinated carbon films deposited by plasma enhanced chemical vapor depositionThe effect of annealing in an ultrahigh vacuum on the chemical structure of diamondlike carbon ͑DLC͒ was investigated using photoelectron spectroscopy, thermal desorption spectroscopy, electrical resistivity, and micro-Raman spectroscopy measurements. The line shapes of the C 1s photoelectron spectra depended on annealing temperature. The relative intensities of four chemical components in the spectra were quantitatively evaluated: sp 3 carbon with carbon-carbon bonds ͑C-C sp 3 carbon͒, sp 2 carbon with carbon-carbon bonds ͑C-C sp 2 carbon͒, sp 2 carbon with hydrogen-carbon bonds ͑H-C sp 2 carbon͒, and sp 3 carbon with hydrogen-carbon bonds ͑H-C sp 3 carbon͒. The variation of the ratio of the components demonstrated that hydrogen in DLC is emitted to the outside in between 450 and 600°C, and the remaining DLC is graphized above 600°C. The increase in the asymmetry of the C 1s spectra and the decrease in the electrical resistivity of the DLC film with annealing temperature agree with the picture that the H-C bonds in DLC produces large free spaces in the structure, which inhibit conductive routes and lead to high electrical resistivity.

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“…CdS-S 2p [29] 163.9 162.7 161.7 158.56 3.14 0.002 ZnS-S 2p [28] 164.0 162.4 161.4 157.69 3.71 0.002 CdS-S 2s [29] 226.0 224.7 223.8 220.66 3.14 0.001 ZnS-S 2s [28] 229 [75] 284.20 [71] 284.30 [5,74] 284.35 [76] 284.45 [77] 283.50-289.30 [78][79][80] z = 0 and 12 correspond to an isolated C atom and a C atom in the diamond bulk, respectively. z = 2, 3, 4, and 5.335 correspond to the atomic CN of graphene/CNT edge, graphene interior, diamond surface and bulk graphite, respectively Figure 16.11 plots CN dependence of the C1s energy E 1s (z) of carbon allotropes.…”

Section: Number-of-layer Dependence Of Graphenementioning

confidence: 98%

Electrons: Entrapment and Polarization

Sun

2014

Springer Series in Chemical Physics

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Qualitative analysis of a diamondlike carbon film by angle-resolved x-ray photoelectron spectroscopy

Cited by 39 publications

References 48 publications

X‐ray photoelectron analysis of surface functional groups on diamond‐like carbon films by gas‐phase chemical derivatization method

X‐ray photoelectron analysis of surface functional groups on diamond‐like carbon films by gas‐phase chemical derivatization method

Annealing effect on the chemical structure of diamondlike carbon

Electrons: Entrapment and Polarization

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