In this paper, we reported the optical constants and dissipation electrical energy of MWC�NTs synthesized on Cu-Ni nanoparticles in hydrogenated amorphous carbon with diferent Ni layer thicknesses using capacitance coupled radio frequency plasma enhanced chemi�cal vapor deposition (RF-PECVD) system. It can be seen that the Multi-Walled Carbon Nanotubes, MWCNTs, synthesized have maximum value of the average diameters in flms deposited with 15 nm Ni layer thickness. With increase of Ni layer thickness, the dielec�tric relaxation time peaks nearly obtain a blue shift. The RBS spectra results shown that Ni nanoparticles successfully was presented in thin flms. Due to the maximum value of the trapping incident photons on flms surface, flms deposited with 5 nm Ni layer thick�ness have maximum value of the absorption edge. The values of the free carriers electric susceptibility, χc, in thin flms with 15 nm Ni layers thickness, for all range wavelengths, have maximum values and they were increased with increasing wavelength. Films depos�ited with 10 nm Ni layer thickness have the maximum value of dissipation factor
