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Abstract
The stress evolution in diamond films grown on Ti6Al4V was investigated in order to develop a comprehensive view of the residual stress formation. Residual stress is composed of intrinsic stress induced during diamond film growth and extrinsic stress caused by the different thermal expansion coefficients between the film and substrate. In the coalescence stage it has been observed that the residual stress is dominated by the microstructure, whereas on continuous films, the thermal stress is more important. In this work diamond thin films with small grain size and good size and good quality were obtained in a surface wave-guide microwave discharge, the Surfatron system, with a negative bias voltage applied between the plasma shell and substrate. For above of -100V applied bias, the ratio of carbon sp³/sp² bond may increase and the nucleation rate increase arising the high value at the -250V applied bias. Stress measurements and sp³ content in the film were studied by Raman scattering spectroscopy. The total residual stress is compressive and varied from -1.52 to -1.48 GPa between 0 and -200 V applied bias, respectively, and above the -200 V, the compressive residual stress increased drastically to -1.80 GPa. The diamond nucleation density was evaluated by top view SEM images.
Highlights
Diamond thin films grown by chemical vapor deposition (CVD) have been studied because of their unique properties, such as, high hardness, very low friction coefficient, biocompatibility, etc
The difficulty of fast diamond nucleation on Ti6Al4V was overcome with a bias enhanced nucleation (BEN) between the plasma shell and the substrate
The present analysis shows that the total residual stress in diamond films can only be explained if other sources of internal stress generation can be identified, such as, the formation of the TiC interface and deposition temperature
Summary
Diamond thin films grown by chemical vapor deposition (CVD) have been studied because of their unique properties, such as, high hardness, very low friction coefficient, biocompatibility, etc. They are very promising for a number of mechanical, biological and chemical applications[1,2,3,4,5]. It is extremely difficult to nucleate and grow diamond on several metallic alloys because the rapid carbon diffusion, for instance, within titanium based materials. This behavior may promote a substantial decrease of carbon concentration on the surface and dropping diamond nucleation and growth. The cluster structure formed at the beginning of this process is not completely clear; it is considered a hydrogenated sp[2] rich amorphous carbon cluster, which can be regarded as a precursor of the diamond nucleus
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