This work aimed to the study of the modifications of the properties of carbon amorphous hydrogenated films (a-C:H) trough the treatment of the surface film with plasma of carbon tetra fluoride (CF4) and Argon. Another object has been the study of the tribological properties of carbon amorphous fluorinated and hydrogenated (a-C:F:H) deposited on substrates of stainless steel 316L. The first part of the these describes the functionalization by plasma of the surfaces with fluorine of films previously deposited of a-C:H on crystalline silicon 100 by the technique of plasma enhanced chemical vapor deposition PECVD. This functionalization was made by the use of plasma of a mixture of CF4 and Argon gases in different proportions. The films had their surfaces analyzed by photoelectron spectroscopy, atomic force microscopy and their surface energies calculates by measurement of the angle contact of three different liquids (water, glycerol and bromonaphthalene). The functionalization with Fluorine made the surface super hydrophobic, reaching values for the contact angle around 140 degrees. In the second part of the these we describe the successful deposition by PECVD of films of carbon amorphous fluorinated on stainless steel 316L. In order to improve the adhesion, the substrates were submitted to treatment with nitriding and carbonitriding by plasma and the subsequent deposition of a film of titanium and a-C:H. In these films were realized measurements of atomic force microscopy, hardness, photoelectron spectroscopy and tribometry to determine the friction coefficient and the resistance to mechanical wastage. The results obtained showed that an incorporation of CF4, produces films with properties similar to teflon properties. We obtained films with hardness around 11 Gpa, harder than stainless steel 316L, whose hardness is approximately 4,5 Gpa, but smaller than the measure in nitrated steel. In relation to the friction coefficient, the film of a-C:F:H presented a significant reduction in relation to the steel and nitrated steel. The tribometry measurements also showed that the film was well adhered and present good resistance to mechanical wear, resisting to hundreds of cycles with the point of the tribometry dragging on the surface with applied force of 10N. As result we get to deposit films on stainless steel 316L with low friction coefficient, elevated hardness and good resistance to mechanical wear.