Abstract: Laminated layers including semiconductor or metal thin layers and insulative thin layers are formed on a substrate and after the laminated layers are patterned, and the laminated layers are oxidized from their side to form an oxidized area. This way, a 0-dimensional quantum box or one-dimensional quantum line having fine tunnel junctions surrounded by the oxidized area and a 0-dimension quantum box or a one-dimensional quantum line made of semiconductor or metal area interposed between the oxidized area and the insulative thin layers are formed in the laminated layers.

Abstract: A method for forming an improved trench isolation having a conformal liner oxide and rounded top and bottom corners in the trench was achieved. The conformal liner oxide improves the CVD gap-filling capabilities for these deep submicron wide trenches, and the rounded corners improve the electrical characteristics of the devices in the adjacent device areas. After etching trenches with vertical sidewalls in the silicon substrate, a two-step oxidation process is used to form the conformal liner oxide. A first oxidation step using a low-oxygen flow rate and a low temperature (about 850 to 920.degree. C.) is used to achieve rounded bottom corners. A second oxidation step at a low-oxygen flow rate and a higher temperature (about 1000 to 1150.degree. C.) is used to achieve rounded top corners. The two-step process also results in a more conformal liner oxide.

Abstract: The present invention proposes a method for fabricating field oxide regions for isolation by an improved poly-buffered local oxidation of silicon (PBLOCOS) process. A polysilicon layer is utilized to reduce the bird's beak, and a thin thermal oxide film is formed on the buffered polysilicon film to prevent pitting formation. Forming a thin pad oxide and a silicon layer, a thermal oxidation is carried out to grow another pad oxide on the silicon layer and crystallize the silicon into polysilicon. The buffered layer of stacked oxide-polysilicon-oxide layer is thus formed. The silicon nitride layer is then deposited on the stacked buffered layer and the active areas are defined. A thermal oxidation is now performed, and thick field oxide regions are grown. After the masking nitride layer and the stacked buffered layer are stripped, the MOS devices are fabricated, and thus complete the present invention.

Abstract: Disclosed are an isolation film of a semiconductor device and a method for fabricating the same, which prevent the isolation film from being damaged due to misalignment when forming a contact hole in a region adjacent to the isolation film, to ensure stable effective isolation distance. The isolation film of a semiconductor device includes a semiconductor substrate, a lower isolation film formed in the semiconductor substrate, and an upper isolation film formed on the lower isolation film, with a material having etching selectivity different from the lower isolation film.

Abstract: A stacked layer including a first oxide, a nitride layer, a second oxide layer and an oxynitride layer is formed on the top of the first oxide layer. An etching is performed through a photoresist to etch the oxynitride, the second oxide and nitride. Oxide spacers are formed on the side walls of the pattern structure, the oxynitride layer is also removed during the formation of the oxide spacers. Trenches are generated by a dry etching technique. The second oxide and the oxide spacers are removed. Next, a thermal oxidation is performed to rounding the corners of the trench openings. A gap filling material is refilled into the trenches and formed on the nitride. Next, a chemical mechanical polishing (CMP) is used to remove the top of the CVD-oxide and the nitride layer. The residual nitride layer, the CVD-oxide and pad oxide are removed to create trench isolation structures with rounding corners.

Abstract: A semiconductor device having an adjacent P-well and N-well, such as a complementary metal oxide semiconductor (CMOS) transistor, on a silicon on insulator (SOI) substrate has a latch-up problem caused by the parasitic bipolar effect. This invention provides a semiconductor device removing the latch-up problem and methods for fabricating the same. A semiconductor device according to the present invention has a T-shaped field oxide layer connected to a buried oxide layer of the SOI substrate to prevent the latch-up problem.

Abstract: A method is disclosed of manufacturing improved device structures which include a device structure having STI and a thin foot charge drain beneath the device area on an inexpensive bulk silicon substrate. The structures retain high speed operation of SOI devices without any adverse effects of charge build-up and floating effects as observed in conventional SOI devices, and, furthermore, are constructed without any extra process steps added to the conventional STI technology except for an isotropic etching step. The invention also contemplates construction of multi-level electronic circuit.

Abstract: A method for forming buried oxide regions below a single crystal semiconductor layer incorporating the steps of forming epitaxial layers having different rates of oxidation with the lower layer having a faster rate of oxidation and oxidizing the layers through an opening in a mask. A plurality of oxide isolated FET's may be formed. The invention reduces the problem of source/drain parasitic capacitance and short channel effects while isolating FET's and eliminating floating body effects of an FET by selectively oxidizing semiconductor layers.

Abstract: A method of forming a trench isolation is disclosed. The initial step includes forming a first dielectric layer on a substrate of a transistor followed by a second dielectric layer formed on the first dielectric layer. Next, the substrate, the first dielectric layer and the second dielectric layer is patterned and etched to form a trench in the substrate, the first dielectric layer and the second dielectric layer. Next, a third dielectric layer is formed on the surface of the side wall of the trench followed by isotropically etching the bottom of the trench. Finally, a fourth dielectric layer on the surface of the trench is formed and the trench is filled with a dielectric material.

Abstract: A method of fabricating a SOI substrate is disclosed, which includes the steps of: forming trenches in the Si substrate; forming an oxidation preventing film over the Si substrate and at the side-walls of the trenches; forming grooves at the bottoms of trenches by etching the Si substrate using the oxidation preventing film as a mask; carrying out an oxidation using to form an oxide film and a Si device layer isolated by the oxide film; removing the oxidation preventing film; and carrying out a planarization to form the silicon-on-insulator substrate having a planar surface.

Abstract: An improved process and structure for channel stop in silicon on insulator using LOCOS isolation are disclosed. Advantages include decreased ion dose requirements; reduced processing time; smaller .DELTA.W characteristics, thus, small transistor size and more precise process control over the edge of a MOSFET. The process also makes possible a wide range of transistor design capabilities and improved transistor operating parameters.

Abstract: The present invention relates to a method of manufacturing a semiconductor device for forming an insulated gate field effect transistor in a completely isolated SOI layer, and has for its object to prevent depletion or inversion surely by introducing impurities of sufficiently high concentration into an SOI layer adjacent to an isolating film filled up between element regions of the SOI layer and a backing insulating layer and to aim at flattening of the SOI substrate surface, and further, includes the steps of implanting impurity ions into a semiconductor layer from an oblique direction so as to reach the semiconductor layer under an oxidation-preventive mask using the oxidation-preventive mask as a mask for ion implantation, heating the semiconductor layer in an oxidizing atmosphere with the oxidation-preventive mask so as to form a local oxide film to isolate the semiconductor layer, and also forming a impurity region with impurities implanted into the semiconductor layer in a region adjacent to the local

Abstract: A semiconductor processing method of forming a static random access memory cell having an n-channel access transistor includes, providing a bulk semiconductor substrate; patterning the substrate for definition of field oxide regions and active area regions for the n-channel access transistor; subjecting the patterned substrate to oxidizing conditions to form a pair of field oxide regions and an intervening n-channel access transistor active area therebetween, the field oxide regions having respective bird's beak regions extending into the n-channel access transistor active area, the n-channel access transistor active area defining a central region away from the bird's beak regions; and conducting a p-type V.sub.T ion implant into the n-channel active area using the field oxide bird's beak regions as an implant mask to concentrate the V.sub.T implant in the central region of the active area.

Abstract: One NPN or PNP transistor is formed on a Si single crystal island having a crystal orientation which is the same as that of a Si substrate and formed into an island shape through an insulation and separation layer on the Si substrate so as to form a semiconductor apparatus which has no parasitic junctions.