Physicochemical and Mechanical Performance of Freestanding Boron-Doped Diamond Nanosheets Coated with C:H:N:O Plasma Polymer

Physicochemical and Mechanical Performance of Freestanding Boron-Doped Diamond Nanosheets Coated with C:H:N:O Plasma Polymer

The physicochemical and mechanical properties of thin and freestanding heavy boron-doped diamond (BDD) nanosheets coated with a thin C:H:N:O plasma polymer were studied. First, diamond nanosheets were grown and doped with boron on a Ta substrate using the microwave plasma-enhanced chemical vapor dep...

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Bibliographic Details
Published in:Materials Vol. 13; no. 8; p. 1861
Main Authors: Rycewicz, Michał, Macewicz, Łukasz, Kratochvil, Jiri, Stanisławska, Alicja, Ficek, Mateusz, Sawczak, Mirosław, Stranak, Vitezslav, Szkodo, Marek, Bogdanowicz, Robert
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 15-04-2020
MDPI
Subjects:
Adhesion
Boron
Chemical sensors
Chemical vapor deposition
diamond composite
Diamond films
Diamonds
Elastic deformation
Electromagnetism
Energy dissipation
Graphene
Low level
Magnetron sputtering
Mechanical properties
Microwave plasmas
Morphology
Nanoindentation
Nanomaterials
Nanosheets
Nitrogen
Nylon
Nylon 6
nylon 6.6
optical constants
Plasma enhanced chemical vapor deposition
Polymer films
Polymers
Spectrum analysis
Substrates
Surface energy
Thickness
Poland
United States > US
Japan
Germany
diamond composite
nylon 6.6
magnetron sputtering
optical constants
nanoindentation
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Summary:The physicochemical and mechanical properties of thin and freestanding heavy boron-doped diamond (BDD) nanosheets coated with a thin C:H:N:O plasma polymer were studied. First, diamond nanosheets were grown and doped with boron on a Ta substrate using the microwave plasma-enhanced chemical vapor deposition technique (MPECVD). Next, the BDD/Ta samples were covered with nylon 6.6 to improve their stability in harsh environments and flexibility during elastic deformations. Plasma polymer films with a thickness of the 500-1000 nm were obtained by magnetron sputtering of a bulk target of nylon 6.6. Hydrophilic nitrogen-rich C:H:N:O was prepared by the sputtering of nylon 6.6. C:H:N:O as a film with high surface energy improves adhesion in ambient conditions. The nylon-diamond interface was perfectly formed, and hence, the adhesion behavior could be attributed to the dissipation of viscoelastic energy originating from irreversible energy loss in soft polymer structure. Diamond surface heterogeneities have been shown to pin the contact edge, indicating that the retraction process causes instantaneous fluctuations on the surface in specified microscale regions. The observed Raman bands at 390, 275, and 220 cm were weak; therefore, the obtained films exhibited a low level of nylon 6 polymerization and short-distance arrangement, indicating crystal symmetry and interchain interactions. The mechanical properties of the nylon-on-diamond were determined by a nanoindentation test in multiload mode. Increasing the maximum load during the nanoindentation test resulted in a decreased hardness of the fabricated structure. The integration of freestanding diamond nanosheets will make it possible to design flexible chemical multielectrode sensors.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma13081861