Abstract: A process for making a SOI region and a bulk region in a semiconductor device. The process includes providing a SOI structure. The SOI structure has a thin silicon layer, a buried insulating oxide layer underlying the thin silicon layer, and a silicon substrate underlying the buried insulating oxide layer. Next, a nitride layer is deposited on top of the SOI structure. The SOI structure is exposed by selectively etching portions of the nitride layer. The portion of the nitride layer which is not etched forms the SOI region. The silicon substrate is exposed by selectively etching the remaining portion of the exposed SOI structure. An epitaxial layer is grown on top of the exposed silicon substrate to form the bulk region. The nitride portion above the SOI structure is finally removed.

Abstract: Semiconductor devices having a metal gate electrode and a titanium or tantalum nitride gate dielectric barrier layer and processes for fabricating such devices are provided. The use of a metal gate electrode along with a titanium or tantalum nitride gate dielectric barrier layer can, for example, provide a highly reliable semiconductor device having an increased operating speed as compared to conventional transistors.

Abstract: A process for making a SOI region and a bulk region in a semiconductor device. The process includes providing a SOI structure. The SOI structure has a thin silicon layer, a buried insulating oxide layer underlying the thin silicon layer, and a silicon substrate underlying the buried insulating oxide layer. Next, a nitride layer is deposited on top of the SOI structure. The SOI structure is exposed by selectively etching portions of the nitride layer. The portion of the nitride layer which is not etched forms the SOI region. The silicon substrate is exposed by selectively etching the remaining portion of the exposed SOI structure. An epitaxial layer is grown in top of the exposed silicon substrate to form the bulk region. The nitride portion above the SOI structure is finally removed.

Abstract: A method of forming an insulated well in an upper portion of a silicon substrate, including the steps of providing a structure of silicon-on-insulator type including a silicon substrate, an insulating layer, and a thin single-crystal silicon layer; removing the insulating layer and the thin silicon layer outside locations where the insulated well is desired to be formed; growing an epitaxial layer; performing a planarization; and making a vertical insulating wall above the periphery of the maintained portion of the thin insulating layer.

Abstract: The present invention is a semiconductor device having and a method for forming wells by growing an epitaxial silicon layer wherein the epitaxial silicon layer has at least three silicon sublayers. The first sublayer is highly doped, the second sublayer is less doped, and the third sublayer is also highly doped. The use of the epitaxially grown wells allows for the placement of high dopant concentrations in regions of the well where electrical isolation is an issue and the placement of lower doped concentrations in regions of the well where electrical isolation is not as great an issue in order to help reduce the problem of parasitic capacitance.

Abstract: Surface to surface electrical isolation of integrated circuits has been achieved by forming N type moats that penetrate the silicon as deeply as required, including across the full thickness of a wafer. The process for creating the moats is based on transmutation doping in which naturally occurring isotopes present in the silicon are converted to phosphorus. Several methods for bringing about the transmutation doping are available including neutron, proton, and deuteron bombardment. By using suitable masking, the bombardment effects can be confined to specific areas which then become the isolation moats. Four different embodiments of the invention are described together with processes for manufacturing them.

Abstract: A method of fabricating a high power bipolar junction transistor. A P-type substrate having an N-type buried region is provided and a trench is formed within the substrate to expose the buried region. N-type ions are implanted and driven into the sidewall of the trench to form a sinker. Since the area and the depth of implantation are larger and deeper than that in prior art, the concentration of the sinker is more uniform and the diffusion range is easily controlled. An N-type epitaxial layer is then formed in the trench and an emitter, a base and their contacts are formed by conventional technique.

Abstract: A process for producing a semiconductor substrate is provided which comprises providing a first member having a porous monocrystalline silicon layer and a nonporous monocrystalline silicon layer grown thereon, laminating the nonporous silicon layer of the first member onto a second member with interposition of an insulation layer provided on at least one lamination face of the first member and the second member, and removing the porous monocrystalline silicon layer by etching, wherein the nonporous monocrystalline silicon layer is grown at a low growth rate controlled such that the density of remaining pores on the crystal growth face is not more than 1000/cm.sup.2 at the time when the nonporous silicon layer has grown to a thickness corresponding to the diameter of the pores of the porous monocrystalline silicon layer.

Abstract: The present invention provides a fabrication process for fabricating a semiconductor integrated circuit device on a silicon substrate having an active device region isolated from the underlying substrate similar to a silicon on insulator(soi) substrate structure. The quasi-soi structure provides an inexpensive semiconductor integrated circuit device having a reduced floating body effect. The process for fabricating the substrate for use in fabricating the quasi-soi semiconductor device includes the steps of providing a silicon substrate member, fabricating at least one passivation layer consisting of silicon nitride over the silicon substrate member and protecting an underlying substrate surface region for subsequent fabrication of isolation trench regions, fabricating the isolation trench regions by etching portions of the passivation layer and portions of the substrate surface region forming an epitaxial silicon growing region.

Abstract: In a method for producing a semiconductor substrate completed through a bonding process for joining a semiconductor wafer to a support substrate by performing heat treatment thereto in a state in which the semiconductor wafer is closely joined to the support substrate, the method according to the present invention includes the following steps, i.e., a depositing process for depositing a poly-crystal semiconductor which covers all areas of a surface to be bonded on the surface of the semiconductor wafer; a heat treatment process for performing the heat treatment to the semiconductor wafer provided after the depositing process, during a predetermined time under a temperature equal to or higher than the heat treatment temperature at the bonding process; and a polishing process for flattening the surface of the poly-crystal semiconductor provided after the heat treatment process. After the above processes were performed in order, the bonding process is performed after the polishing process.

Abstract: A heteroepitaxial semiconductor device having reduced density of threading dislocations and a process for forming such a device. According to one embodiment, the device includes a substrate which is heat treated to a temperature in excess of 1000.degree. C., a film of arsenic formed on the substrate at a temperature between 800.degree. C. and 840.degree. C., a GaAs nucleation layer of less than 200 angstroms and formed at a temperature between about 350.degree. C. and 450.degree. C., and a plurality of stacked groups of layers of InP, wherein adjacent InP layers are formed at different temperatures.

Abstract: A memory cell of a semiconductor dynamic random access memory device requires a bit line contact hole open to a drain region of a cell transistor for connecting a bit line to the drain region and a node contact hole open to a source region for connecting a storage electrode of a stacked capacitor to the source region, and the bit line contact hole and the node contact hole are plugged with silicon layers; the silicon layers are epitaxially grown from the source and drain regions over an oxide-encapsulated gate electrode of the cell transistor so as to increase the contact areas; and the silicon layers are firstly anisotropically grown until reaching the upper surface of the oxide-encapsulated gate electrode, and, thereafter, isotropically grown so as to increase the contact areas.

Abstract: An isolation method for a highly-integrated semiconductor device includes growing an epitaxial layer on the entire surface of a semiconductor substrate including over a trench on which an oxide layer is formed, thereby leaving the inside of the trench empty. A portion of the epitaxial layer which is located over the trench is then oxidized to form an isolation region.

Abstract: A method for determining a coding type and a coding mode for object shape coding is disclosed. A coding mode is determined according to the characteristic of an object and shape, and the shape is coded by varying a coding method according to the determined coding mode.

Abstract: After partially burying an insulation layer in a first single-crystalline silicon substrate, and flattening, the first single-crystalline silicon substrate and a second single-crystalline substrate are formed with a low impurity concentration epitaxial layer. By grinding and polishing the first single crystalline silicon substrate, an ultra thin film SOI layer having thickness of about 0.1 .mu.m is formed. On the ultra thin film SOI layer, an insulation layer 8 for isolation is formed. Thus, an SOI substrate for integrating the power element and a control circuit element including the ultra thin film SOI layer in one chip can be provided.

Abstract: Methods of forming semiconductor-on-insulator field effect transistors include the steps of forming an insulated trench containing a semiconductor region therein and an insulating region mesa at a bottom of the trench, so that the semiconductor region has relatively thick regions adjacent the sidewalls of the trench and has a relatively thin region above the mesa. Dopants can then be added to the thick regions to form low resistance source and drain regions on opposite sides of the thin region which acts as the channel region. Because the channel region is thin, low junction capacitance can also be achieved. An insulated gate electrode can also be formed on the face of the semiconductor region, above the channel region, and then source and drain contacts can be formed to the source and drain regions to complete the device.

Abstract: A high-frequency wireless communication system on a single ultrathin silicon on sapphire chip is presented. This system incorporates analog, digital (logic and memory) and high radio frequency circuits on a single ultrathin silicon on sapphire chip. The devices are fabricated using conventional bulk silicon CMOS processing techniques. Advantages include single chip architecture, superior high frequency performance, low power consumption and cost effective fabrication.

Abstract: A method of producing a high quality silicon surface prior to carrying out a selective epitaxial growth of silicon process for forming an active device region on a substrate. The process flow of the present invention eliminates the need for the sacrificial oxidation layer typically used in such processes. After the etching of a seed hole through the isolation oxide layer using a reactive ion etch a short, low power C.sub.2 F.sub.6 etch is performed. The present invention provides a simple and cost-effective way to eliminate reactive ion etch damage prior to SEG growth because the dry C.sub.2 F.sub.6 etch can be done in the same etch reactor in which the seed hole oxide etch is performed. In addition, the re-oxidation (sacrificial oxide) step is eliminated, reducing the number of process steps.

Abstract: An isolation layer structure of a semiconductor device includes a substrate; a first insulating layer having a predetermined width and thickness which is formed in a predetermined portion of the substrate; and a second insulating layer which is formed in a predetermined portion of the substrate and which surrounds the first insulating layer.

Abstract: A semiconductor film deposited on a substrate has regions of different thermal conductivity. A pulsed laser radiation is applied to the semiconductor film to melt the semiconductor film. When the melted semiconductor film is cooled and solidified, localized low-temperature regions are developed in the respective regions of different thermal conductivity. Crystal nuclei are produced in the respective localized low-temperature regions and grown into a single semiconductor crystal. The regions of different thermal conductivity are formed in the semiconductor film by high-thermal-conductivity members deposited on the semiconductor film in thermally coupled relationship thereto. A semiconductor device is fabricated using the semiconductor film and has channels disposed in the vicinity of the crystal nuclei.

Abstract: A fabrication method of a semiconductor device that can realize a semiconductor device having an improved radiation performance of heat together with a low parasitic capacitance between a semiconductor substrate and a conductor of the device. An SOI structure having a single-crystal silicon layer formed on an insulating substructure is prepared and then, device regions are formed on the substructure by using the single-crystal silicon layer. Sidewall insulators are formed to cover side faces of the respective device regions, laterally isolating the device regions from each other. A resistive silicon layer is formed on a non-device region of the substructure. The resistive silicon layer has a resistivity or specific resistance greater than that of the device regions. Electronic elements are formed in the device regions. The resistive silicon layer may be made of polysilicon or single-crystal silicon.