The topic of this thesis is the laser-based synthesis and modification of graphitic materials. Graphitic materials are in the focus of the current scientific research and becoming increasingly important in many promising applications. Besides micro- and nanoelectronic applications graphitic materials are promising fillers in polymer composites. The aim of this thesis is to demonstrate that laser-based methods can be beneficial for the synthesis and selective surface modification of graphitic interfaces. Because of the small experimental effort and the high flexibility of laser-based methods, new ways of production, modification and functionalization of graphitic interfaces for applications in e. g. electronics are feasible. Specifically, the synthesis of graphitic interfaces on SiC single crystal by an ultraviolet continuous-wave laser (λ = 355 nm) is presented in this thesis. By laser processing local graphitic structures can be built up. These graphitic structures are characterized and the underlying mechanism is discussed. Furthermore, it is demonstrated that the surface properties of graphitic materials can be engineered via functional organic layers in combination with a laser induced process. First graphitic substrates (highly oriented pyrolytic graphite, HOPG) are coated with a self assembled monolayer (SAM). Subsequently through local induced bromination with an argon ion laser beam (λ = 514 nm) bromine groups are introduced into the SAMs. This can be the starting point for further chemical modifications. The last part of the thesis shows the great flexibility and the possibility of simple upscaling of laser-based methods. Here a method is presented, with which it is possible to adjust the wetting behaviour of graphite/polymer composites. The aim was to improve the water management in a PEM fuel cells which are produced out of this graphite/polymer compound. For this purpose, a combination of a coating routine and laser processing with a pulsed nanosecond laser (λ = 514 nm) is used.