Conventional DC magnetron sputter deposition from a carbon target with argon as the sputtering gas is limited by a low deposition rate, and the resultant coatings have low diamond-like sp 3 content. Here we study arc-mixed mode high power impulse magnetron sputtering (HiPIMS) of carbon using He, Ne, Ar, Xe and Kr gases and show an increase in deposition rate is achieved by using noble gases heavier than argon. On the other hand, a higher sp 3 fraction is achieved by using noble gases lighter than argon. The higher deposition rate of the heavier noble gases is attributed to the higher sputtering yield and an earlier arc onset owing to their lower ionization potential . The higher sp 3 fraction achieved by lighter noble gases is attributed to stress generation by knock-on collisions at the surface of the depositing film, in the absence of stress relief created by large thermal spike volumes. When neon was used as the sputtering gas, the inert gas content was higher than for any other noble gas. Our results lead to opportunities for grading the sp 3 content with depth simply by changing the gas composition, allowing fabrication of buried conductive channels in ta-C, Metal-Insulator-Metal (MIM) (low sp 3 /high sp 3 /low sp 3 ) structures and biosensor films (high sp 3 /low sp 3 ). • Arc-mixed mode HiPIMS deposition of carbon films with He, Ne, Ar, Xe, and Kr noble gases. • The highest sp 3 fraction is achieved by He-Ne mixtures, attributed to effective momentum transfer. • The density and compressive stress in the films decrease with increasing size of noble gas atoms. • The results suggest creating buried conduction channels by changing the sputter gas composition.