This thesis is a contribution to the development of AlGaN/GaN HEMTs on silicon substrates for low frequency and applications under high voltages (typically 600V) as switches for home automation or power circuits of electric vehicles. It was conducted in close collaboration with Picogiga who made all epitaxy. It is composed of three parts: development of manufacturing technology, study of leakage currents, improving the insulating barrier and search behavior “normally”.The realization of low resistivity ohmic contacts is the crucial step in the manufacture of AlGaN / GaN HEMTs power. Optimization of the stack of metal used, the temperature and annealing time and the search for a compromise on the distance metallization - electron gas, has allowed us to achieve ohmic contacts around the state s (0.5 Ohm. mm).The origin of the leakage current has been systematically studied in five different kinds epitaxy. The distance gate - drain and leakage currents were both identified as being factors limiting the breakdown voltage. According to the structure, the leakage currents take place either through the grid (~ e-8 A/mm at 210V), or in parallel to the channel (e-5A/mm). In both cases, these currents are comparable to leakage currents through the buffer (ie current measured between two mesas). These leakage currents were attributed to transition layers required for the adaptation of the epitaxial nitride layers on the silicon substrate. Achieving AlGaN HEMT / GaN on silicon for high voltage applications pass through to an improvement in these buffer layers.We have demonstrated that it is possible to improve the insulation of the AlGaN barrier through hydrogenation of the material. In effect a surface treatment by a hydrogen plasma allows, by diffusion, to incorporate hydrogen which passivates the through dislocations. After treatment, the gate leakage current is reduced and the breakdown voltage of 400V is pushed with leakage currents of the order e-6A/mm. Under these conditions, when the breakdown occurs at the surface of the sample, is no longer limited by the gate-drain distance. This result opens the way for the realization of HEMT with high breakdown voltage (V ~ 600V).The effect of plasma fluorinated SF6 on the electrical characteristics of the HEMT (AlN/GaN)/GaN (barrier is AlN/GaN superlattices) was studied for the first time in this thesis. The fluorine ions incorporated in the barrier act as donors that increase the density of the two-dimensional gas of electrons and the shifting to the voltage clamping negative voltages. This effect is opposite to that observed in the HEMT in AlGaN barrier. This result eliminates the possibility of the HEMT (AlN/GaN)/GaN "normally off" by fluorine doping, a simple and effective technique that gives good results on AlGaN HEMT barrier. On the other hand, it brings some experimental answers to theoretical predictions using fluorine doping for n-type or p in III nitrides.