Friction Behavior of Diamond-like Carbon Films with Varying Mechanical Properties

R. Arbind Singh, Eui-Sung Yoon, Hong Joon Kim, Hosung Kong, Se-Jun Park, Kwang-Ryeol Lee
 

Diamond-like carbon (DLC) films deposited on silicon wafer with varying film thickness were investigated for their micro-scale friction behaviour. Films with three different thicknesses, namely 100nm, 500nm and 1000nm, deposited by a radio frequency plasma-assisted chemical vapor deposition method on Si (100) wafer, were used as the test samples. The elastic modulus of the DLC samples increased with their film thickness. The micro-scale friction tests were conducted in a ball-on-flat type micro-tribotester, using soda lime glass balls with different radii (0.25mm, 0.5mm and 1mm), and with varying applied normal load (load range: 1500mN to 4800mN). Results showed that the friction force increased with applied normal load, whereas with respect to the ball size, two different trends were observed.In the case of 100nm thick sample, friction increased with the ball size at any given normal load, while for 500nm and 1000nm thick samples, friction had an inverse relation with the ball size at all applied normal loads. The friction behavior in the case of the 100nm thick film was adhesive in nature, whereas for the thicker films plowing was dominant. The friction behavior of the test samples with the ball size, which was distinctly different, was discussed in terms of the contact area, influenced by their mechanical property, namely, the elastic modulus.