Abstract: A method of fabricating a semiconductor device which includes the steps of forming a trench (4), and repeating the formation and removal of an oxide film (a sacrificial oxide film) twice to provide a rounded configuration (5b) of an opening portion of the trench (4) and a rounded configuration (6b) of a bottom thereof and to draw defects in a semiconductor layer into a silicon oxide film (8), reducing the defects adjacent the inner wall of the trench (4), whereby electric field concentration on a gate is prevented and the mobility of carriers in channels is improved for an improvement in characteristic, particularly an on-state voltage, of a power device.

Abstract: An n-drift region, a p-base region, and an n-emitter region are formed in a semiconductor substrate. A trench is formed to be in contact with n-emitter region and p-base region, and a gate electrode is formed in trench with an insulated gate layer interposed. A first metal electrode layer electrically connected to n-emitter region, and a second metal electrode layer electrically connected to p-base region are provided. A direct current power source apparatus is connected to first and second metal electrode layers. Accordingly, on-state voltage can be reduced.

Abstract: In a miniaturized complete CMOS SRAM of a TFT load type, a field effect thin-film transistor (TFT) can achieve stable reading and writing operation of a memory cell and can reduce power consumption thereof. The field effect thin-film transistor formed on an insulator includes an active layer and a gate electrode. The gate electrode is formed on a channel region of the active layer with a gate insulating film therebetween. The active layer is formed of a channel region and source/drain regions. The channel region is formed of a monocrystal silicon layer and does not includes a grain boundary. The source/drain regions is formed of a polysilicon layer. The channel region has a density of crystal defects of less than 10.sup.9 pieces/cm.sup.2. The thin film transistor shows an ON current of 0.25 .mu.A/.mu.m per channel width of 1 .mu.m and an OFF current of 15 fA/.mu.m. The thin-film transistor can be applied to a p-channel MOS transistor serving as a load transistor in a memory cell of a CMOS type SRAM.

Abstract: A semiconductor device including a layer formed without being affected by a stepped ground pattern and a method of fabricating the semiconductor device are disclosed. Cap portions (30) (insulating layers) formed over trenches (13) and covering doped polysilicon (5) have an inclined surface (26) which satisfies Y/X <5 where X is the length of the inclined surface (26) in a direction of the surface of a body (50) and Y is the height of the inclined surface (26) from the surface of the body (50). Formation of the insulating layers having the smooth inclined surface satisfying Y/X<5 permits a first main electrode to be formed nondefectively without being affected by the ground pattern including the insulating layers.

Abstract: In a miniaturized complete CMOS SRAM of a TFT load type, a field effect thin-film transistor (TFT) can achieve stable reading and writing operation of a memory cell and can reduce power consumption thereof. The field effect thin-film transistor formed on an insulator includes an active layer and a gate electrode. The gate electrode is formed on a channel region of the active layer with a gate insulating film therebetween. The active layer is formed of a channel region and source/drain regions. The channel region is formed of a monocrystal silicon layer and does not includes a grain boundary. The source/drain regions is formed of a polysilicon layer. The channel region has a density of crystal defects of less than 10.sup.9 pieces/cm.sup.2. The thin film transistor shows an ON current of 0.25 .mu.A/.mu.m per channel width of 1 .mu.m and an OFF current of 15 fA/.mu.m. The thin-film transistor can be applied to a p-channel MOS transistor serving as a load transistor in a memory cell of a CMOS type SRAM.

Abstract: A semiconductor layer, through which a main current flows, is so structured that a carrier life time in the semiconductor layer is ununiform in accordance with a predetermined distribution of the carrier life time. Thus, turn OFF characteristics of a semiconductor switching device can be improved without causing any unacceptable disadvantages for other characteristics.

Abstract: A semiconductor device including a layer formed without being affected by a stepped ground pattern and a method of fabricating the semiconductor device are disclosed. Cap portions (30) (insulating layers) formed over trenches (13) and covering doped polysilicon (5) have an inclined surface (26) which satisfies Y/X .ltoreq.5 where X is the length of the inclined surface (26) in a direction of the surface of a body (50) and Y is the height of the inclined surface (26) from the surface of the body (50). Formation of the insulating layers having the smooth inclined surface satisfying Y/X.ltoreq.5 permits a first main electrode to be formed non-defectively without being affected by the ground pattern including the insulating layers.

Abstract: A semiconductor layer, through which a main current flows, is so structured that a carrier life time in the semiconductor layer is ununiform in accordance with a predetermined distribution of the carrier life time. Thus, turn OFF characteristics of a semiconductor switching device can be improved without causing any unacceptable disadvantages for other characteristics.

Abstract: A semiconductor substrate having a buffer region in one major surface with the buffer region having a opening portion of prescribed width and depth. An electrode region is in contact with the substrate through the opening portion and is short-circuited with the buffer region by a contact, so that the voltage breakdown characteristics of the device can be easily adjusted through the adjustment of the width and depth of the opening portion and so that the high speed switching and low "on" resistance characteristics can also be obtained.