1. Field of the Invention
The present invention relates to a process for manufacturing a DMOS transistor.
2. Description of the Related Technology
Such a process is known from the printed publication U.S. Pat. No. 5,539,238. Here, a DMOS transistor with a deep trench structure is generated, with the doped regions adjoining the side walls and the base region representing the so-called drift zone of the transistor. Due to the partially vertical implementation of the drift zone along the side walls of the trench, the length of the transistor can be reduced. The disadvantage in this process is that for an applied blocking voltage inhomogeneities in the course of the potential occur on the edges of the trench structure, which cause an undesirable reduction in the transistor blocking voltage. Furthermore, the total length of the drift region is not decreased but only subdivided into a vertical and a lateral share, that is, the specific turn-on resistance Rsp=Rdson/region is not decreased, rather the side walls can only be doped insufficiently; and the specific turn-on resistance, Rsp, and thus the surface area used by the transistor, are increased.
A further process is known from the printed publication EP 0 837 509 A1. Here, a self-adjusted drift region is generated in a DMOS transistor below a LOCOS oxide. The disadvantage is that the doping of the drift region is introduced before oxidation and that the share of the doping agent diffusing into the oxide can be determined with some imprecision only. In addition, the high temperature load during oxidation causes a wide distribution of the doping agent, which in turn leads to a higher imprecision in the doping agent concentration. Furthermore, a large silicon thickness is required underneath the oxide in order to increase the blocking voltage by means of the so-called “RESURF” effect. Overall, the process scatterings increase the scatter in the electrical parameters of the transistor.
One development aim in the area of DMOS transistors is to manufacture space-saving structures which, for an applied blocking voltage, feature low field strengths, in order to avoid a generation of load carriers that lead to a breakthrough within the component. A further aim in the development of DMOS transistors is to achieve a low specific turn-on resistance, Rsp, in order to reduce the spatial area required by such an integrated circuit in the case of integrated circuits where DMOS transistors take up a significant part of the total chip surface area.