Abstract: A semiconductor device comprises a field effect transistor and a passive capacitor, wherein the dielectric layer of the capacitor is comprised of a high-k material, whereas the gate insulation layer of the field effect transistor is formed of an ultra thin oxide layer or oxynitride layer so as to provide for superior carrier mobility at the interface between the gate insulation layer and the underlying channel region. Since carrier mobility in the capacitor is not of great importance, the high-k material allows the provision of high capacitance per unit area while featuring a thickness sufficient to effectively reduce leakage current.

Abstract: The polysilicon gate electrode of a MOS transistor may be substantially completely converted into a metal silicide without sacrificing the drain and source junctions in that a thickness of the polysilicon layer, for forming the gate electrode, is targeted to be substantially converted into metal silicide in a subsequent silicidation process. The gate electrode, substantially comprised of metal silicide, offers high conductivity even at critical dimensions in the deep sub-micron range, while at the same time the effect of polysilicon gate depletion is significantly reduced. Manufacturing of the MOS transistor, having the substantially fully-converted metal silicide gate electrode, is essentially compatible with standard MOS process technology.

Abstract: A method of forming an oxide layer on a substrate comprises deposition of a mask layer with an opening for defining the area where the oxide layer is to be formed, and an ion implantation step performed with a tilt angle so as to obtain a varying ion concentration. In a subsequent single oxidation step, an oxide layer is formed having a thickness that varies in conformity with the ion concentration. This method may advantageously be applied to the formation of a gate insulation layer in a field effect transistor.

Abstract: A method is disclosed in which a lightly doped region in a semiconductor layer is obtained by diffusing dopant atoms of a first and second type into the underlying semiconductor layer. Preferably, the method is applied to the formation of lightly doped source and drain regions in a field effect transistor so as to obtain a required gradual dopant concentration transition from the general region to the drain and source regions for avoiding the hot carrier effect. Advantageously, a diffusion of the dopant atoms is initiated during an oxidizing step in which the thickness of the gate insulation layer is increased at the edge portions thereof.

Abstract: A method is disclosed in which a lightly doped region in a semiconductor layer is obtained by diffusing dopant atoms of a first and second type into the underlying semiconductor layer. Preferably, the method is applied to the formation of lightly doped source and drain regions in a field effect transistor so as to obtain a required gradual dopant concentration transition from the general region to the drain and source regions for avoiding the hot carrier effect. Advantageously, a diffusion of the dopant atoms is initiated during an oxidizing step in which the thickness of the gate insulation layer is increased at the edge portions thereof.

Abstract: A method of forming an oxide layer on a substrate comprises deposition of a mask layer with an opening for defining the area where the oxide layer is to be formed, and an ion implantation step performed with a tilt angle so as to obtain a varying ion concentration. In a subsequent single oxidation step, an oxide layer is formed having a thickness that varies in conformity with the ion concentration. This method may advantageously be applied to the formation of a gate insulation layer in a field effect transistor.