Abstract: A method and a BICMOS structure are provided. The BiCMOS structure includes an SOI substrate having a bottom Si-containing layer, a buried insulating layer located atop the bottom Si-containing layer, a top Si-containing layer atop the buried insulating layer and a sub-collector which is located in an upper surface of the bottom Si-containing layer. The sub-collector is in contact with a bottom surface of the buried insulating layer.

Abstract: A semiconductor-on-insulator structure includes a substrate and a buried insulator layer overlying the substrate. A plurality of semiconductor islands overlie the buried insulator layer. The semiconductor islands are isolated from one another by trenches. A plurality of recess resistant regions overlie the buried insulator layer at a lower surface of the trenches.

Abstract: A semiconductor device includes an elongated, blade-shaped semiconductor element isolated from a surrounding region of a semiconductor substrate by buried and side oxide layers. A polysilicon post disposed at one end of the element has a bottom portion extending through the buried oxide to contact the substrate, providing for electrical and thermal coupling between the element and the substrate and for gettering impurities during processing. A device fabrication process employs a selective silicon-on-insulator (SOI) technique including forming trenches in the substrate; passivating the upper portion of the element; and performing a long oxidation to create the buried oxide layer. A second oxidation is used to create an insulating oxide layer on the sidewalls of the semiconductor element, and polysilicon material is used to fill the trenches and to create the post.

Abstract: An integrated device having a substrate wherein a buried layer and an epitaxial region have been formed, and an isolation structure adapted to define a plurality of isolation wells for integrating the components of the integrated device therein, the isolation structure including plural dielectrically insulated regions or dielectric trenches being filled with a conductive material to form a plurality of contact regions to buried regions of the device, the buried regions including, in particular, the substrate and buried layer.

Abstract: In a semiconductor device having a semiconductor element having a plurality of SOI-Si layers, the height of element isolation regions from the surface of the semiconductor substrate are substantially equal to each other. Alternatively, the element isolation regions are formed at the equal height on the semiconductor substrate and then a plurality of SOI-Si layers appropriately different in thickness are formed. In this manner, it is possible to obtain element isolation regions having substantially the same height from the semiconductor substrate and desired element regions having SOI-Si layers different in height. The thickness of a single crystalline silicon film (SOI-Si layer) may be appropriately changed by another method which includes depositing an amorphous silicon film and applying a heat processing to form an epi layer, and removing an unnecessary portion.

Abstract: A convex polycrystalline silicon film is formed on a handle wafer. A semiconductor layer is formed on the polycrystalline silicon film. The semiconductor is thinner on its areas in which the convex polycrystalline silicon film is formed and is thicker on its areas in which the convex polycrystalline silicon film is not formed. An opening is formed in each of those areas of an insulating film which are located under respective thick-film semiconductor areas of the semiconductor layer. The polycrystalline silicon film is formed in the openings to connect electrically the thick-film semiconductor areas and the handle wafer together.

Abstract: The present invention provides a semiconductor device comprising a single-crystal silicon substrate; and a single-crystal oxide thin film having a perovskite structure formed through epitaxial growth on the single-crystal silicon substrate. The single-crystal oxide thin film is directly in contact with a surface of the single-crystal silicon substrate, and contains a bivalent metal that is reactive to silicon.

Abstract: According to a semiconductor device of the present invention, a field oxide film is formed so as to cover the main surface of an SOI layer and to reach the main surface of a buried oxide film. As a result, a pMOS active region of the SOI and an nMOS active region of the SOI can be electrically isolated completely. Therefore, latchup can be prevented completely. As a result, it is possible to provide a semiconductor device using an SOI substrate which can implement high integration by eliminating reduction of the breakdown voltage between source and drain, which was a problem of a conventional SOI field effect transistor, as well as by efficiently disposing a body contact region, which hampers high integration, and a method of manufacturing the same.

Abstract: The present invention provides a semiconductor device of the SOI-LDMOS type in which the field plate is divided into a plurality of electrically isolated sub-field plates. At least two of the divided sub-field plates are connected to external circuits for reading their respective output voltages. By connecting a first external circuit and a second external circuit having specific components, one is configured for determining an instantaneous output voltage and the other is configured for determining a change in output voltage as a function of time. Power is disconnected from the semiconductor device if either the instantaneous voltage or the derivative of voltage over time exceeds an established value.

Abstract: A semiconductor device comprises an embedded insulation layer 101 formed on a semiconductor substrate 100, plural power semiconductor elements 2, 3 formed on a semiconductor substrate 100 on the embedded insulation layer, a trench 4 formed on the semiconductor substrate and isolating between the power semiconductor elements, and an isolator 5 insulating and driving control electrodes of the power semiconductor elements, and the power semiconductor elements 2, 3 such as transistors can be used, being connected each other in series.

Abstract: A microfabricated device includes a substrate having a device layer and substantially filled, isolating trenches; a doped region of material formed by photolithographically defining a region for selective doping of said device layer, selectively doping said region, and thermally diffusing said dopant; circuits on said device layer formed using a substantially standard circuit technology; and at least one structure trench in the substrate which completes the definition of electrically isolated micromechanical structural elements.

Abstract: A semiconductor device in which the potential of a conductive support substrate can be kept to be a predetermined potential, while an SOI substrate is used as a chip substrate, without adding a new step and providing a rear electrode, is provided. In a chip, on the main surface of a first Si substrate of a P-type, a SiO2 film and a second Si substrate of a P-type are laminated in this order. The chip has, in the second Si substrate, isolation trenches, an outermost isolation trench, a plurality of element forming regions isolated by these trenches, second element forming regions, a peripheral region, and a peripheral region connection wiring which connects a contact region of the peripheral region with a contact region connected with a predetermined potential, for example, a ground potential in the second element forming region surrounded by, for example, the isolation trench.

Abstract: The present invention provides a method for forming low dielectric constant inter-metal dielectric layer. The method comprises providing a semiconductor substrate and forming a first dielectric layer on the semiconductor substrate. Conductor structures are formed in the first dielectric layer. The partial first dielectric layer is removed by using the conductor structures as etch mask. A second dielectric layer is formed between the conductor structure, which has a dielectric constant smaller than the first dielectric layer. The semiconductor structure comprises a substrate, a first dielectric layer on the substrate, multitude of conductor structures in the first dielectric layer, and multitude of second dielectric structures in the first dielectric layer and between the conductor structures.

Abstract: A semiconductor device is fabricated in a silicon on insulator (SOI) substrate including a supporting silicon substrate, a silicon oxide layer supported by the substrate, and a silicon layer overlying the silicon oxide layer. An electrical component is fabricated in the silicon layer over a portion of the silicon oxide layer, and then the substrate opposite from the component is masked and etched. A metal layer is then formed in the portion of the substrate which has been removed by etching with the metal layer providing heat removal from the component. In an alternative embodiment, the silicon oxide layer overlying the portion of the substrate is removed with the metal layer abutting the silicon layer. In fabricating the device, preferential etching is employed to remove the silicon in the substrate with the silicon oxide functioning as an etchant stop. A two step process can be employed including a first oxide etch to etch the bulk of the silicon and then a more selective but slower etch.

Abstract: A silicon-on-insulator semiconductor device and manufacturing method therefor is provided in which a single wafer die contains a transistor over an insulator layer to form a fully depleted silicon-on-insulator device and a transistor formed in a semiconductor island over an insulator structure on the semiconductor wafer forms a partially depleted silicon-on-insulator device.

Abstract: Disclosed herein is a communication module, comprising a semiconductor chip in which channels for allowing signal converting means to convert current signals inputted from input terminals to voltage signals and outputting the same from output terminals respectively are arranged in parallel in plural form, and wherein the semiconductor chip is comprised principally of a semiconductor substrate in which a second semiconductor layer is provided on a first semiconductor layer with an insulating layer interposed therebetween, each of the signal converting means is formed in a channel forming region of the second semiconductor layer, which is defined for each channel, and the input and output terminals are formed on the channel forming regions of the second semiconductor layer with the insulating layer interposed therebetween.

Abstract: A semiconductor manufacturing method has the steps of preparing an SOI substrate having a supporting substrate, an insulating film formed above the supporting substrate, a semiconductor region formed above the insulating film, and an intermediate layer formed between the supporting substrate and the insulating film, forming a semiconductor element in the semiconductor region, and removing the intermediate layer to separate the supporting substrate and the semiconductor region in which the semiconductor element is formed.

Abstract: The present invention relates generally to removing an undesirable second oxide, while minimally affecting a desirable first oxide, on an integrated circuit. The integrated circuit may be part of a larger system.

Abstract: There is provided a method of fabricating a silicon-on-insulator substrate, including the steps of (a) forming a silicon substrate at a surface thereof with an oxygen-containing region containing oxygen at such a concentration that oxygen is not precipitated in the oxygen-containing region in later mentioned heat treatment, (b) forming a silicon oxide film at a surface of the silicon substrate, (c) implanting hydrogen ions into the silicon substrate through the silicon oxide film, (d) overlapping the silicon substrate and a support substrate each other so that the silicon oxide film makes contact with the support substrate, and (e) applying heat treatment to the thus overlapped silicon substrate and support substrate to thereby separate the silicon substrate into two pieces at a region into which the hydrogen ions have been implanted, one of the two pieces remaining on the silicon oxide film as a silicon-on-insulator active layer.

Abstract: An improved silicon on sapphire structure and/or device has one or more buffer layers. In a first preferred embodiment, the buffer layer is layer of silicon oxide material that prevents the stress induced defects in the silicon layer. In an alternative embodiment, the buffer layer comprises two layers. A first silicon oxide layer attached to the silicon to insure a perfect interface between the silicon. A second silicon oxide layer then is attached to the sapphire layer. The first and second silicon oxide layers are then attached, e.g., by a wafer bonding technique. This structure has no conductive paths beneath the oxide insulator(s) and therefore enables improved performance in radio frequency applications.

Abstract: Techniques for etching a wafer layer using multiple layers of the same photoresistant material and structures formed using such techniques are provided. In a method, first, multiple layers of the same photoresist material are formed over the wafer layer to form a composite photoresist layer. The composite photoresist layer is patterned and developed to form a patterned photoresist layer. Exposed portions of the wafer layer are then removed using the pattern photoresist layer. Each of the multiple layers of photoresist may, for example, be formed to a maximum rated thickness for the photoresist material. Structures formed using this process may have relatively small dimensions (e.g., widths of 5 microns or less or a spacing or pitch of 5 microns or less). In addition, structures may also have sidewalls which are relatively long, smooth, and/or vertical.

Abstract: The number of design processes for fabricating semiconductor devices can be reduced by parallel connection of a plurality of unit bipolar transistors Qu that are completely electrically isolated from each other in a semiconductor layer of an SOI substrate 1 to form a bipolar transistor having a large current capacity.

Abstract: Methods and apparatus are provided for creating field effect transistor (FET) body connections with high-quality matching characteristics and no area penalty for partially depleted silicon-on-insulator (SOI) circuits. The FET body connections are created for partially depleted silicon-on-insulator (SOI) technologies by forming adjacent FET devices inside a shallow trench shape. The adjacent FET devices share a common diffusion area, such as source or drain. Selectively spacing apart adjacent gate lines form an underpath connecting bodies of the adjacent FET devices. The underpath is defined by forming an undepleted region on top of a buried oxide layer. The adjacent polysilicon gate lines are selectively spaced apart to define a depth of depletion in a shared diffusion region for creating the underpath. Also, adjacent FET devices with connecting bodies can be built by adding an ion implant masking step to the fabrication process. This masking step changes the depletion depth under the shared diffusion area.

Abstract: The invention relates to a semiconductor integrated circuit and a method of manufacturing the same, and particularly, to prevention of a drop in the performance and reliability of a semiconductor integrated circuit device, which would otherwise be induced by degassing arising in a TEOS/CVD silicon oxide film provided on a back surface of a semiconductor substrate. There are proposed a semiconductor substrate in which a TEOS/CVD silicon oxide film provided on a back surface of the semiconductor substrate is coated with another dielectric film; a semiconductor substrate not having a TEOS/CVD silicon oxide film on a back surface thereof; a semiconductor substrate in which a TEOS/CVD silicon oxide film is removed from a back surface of the substrate; and a semiconductor substrate in which a thin TEOS/CVD silicon oxide film—which involves degassing falling within a tolerance is provided on a back surface of the substrate.

Abstract: Provided are a semiconductor device capable of satisfactorily solving a floating-body problem and a hot carrier problem which often arise in an SOI device and of causing a widely distributed partial isolating film to generate a crystal defect for peripheral structures with difficulty and a method of manufacturing the semiconductor device. A dummy region DM1 having no function as an element is formed at almost regular intervals in a partial isolating film 5b provided between MOS transistors TR1. Consequently, the occupation rate of the dummy region DM1 having a lower resistance value than that of a silicon layer 3b provided under the partial isolating film 5b is increased so that the floating-body problem and the hot carrier problem can be solved.

Abstract: A circuit-incorporating photosensitive device comprising: an SOI wafer including a first silicon substrate, a second silicon substrate, and an oxide film; a photodiode formed in a first region of the SOI wafer; and a signal processing circuit formed in a second region of the SOI wafer, wherein the photodiode includes a photosensitive layer formed of an SiGe layer.

Abstract: A circuit region 2 on a main surface of an SOI substrate, and a isolating region 9b defined by insulating isolation trenches 4a and 4b are connected by a wiring resistor, or a diffused resistor 11a in the SOI substrate. The isolating region 9b and an intermediate region 9 are connected by a wiring resistor, or a diffused resistor 11b in the SOI substrate. Furthermore, a circuit region 3 on a main surface of an SOI substrate, and a isolating region 9c defined by insulating isolation trenches 4c and 4d are connected by a wiring resistor, or a diffused resistor 11d in the SOI substrate. The isolating region 9c and an intermediate region 9 are connected by a wiring resistor, or a diffused resistor 11c in the SOI substrate. As a result, distribution of voltage applied between the circuit regions 2 and 3 by the wiring resistors or the diffused resistors 11a to 11d can increase the withstand voltage of a semiconductor integrated circuit.

Abstract: A microelectromechanical system is fabricated from a substrate having a handle layer, a silicon sacrificial layer and a device layer. A micromechanical structure is etched in the device layer and the underlying silicon sacrificial layer is etched away to release the micromechanical structure for movement. One particular micromechanical structure described is a micromirror.

Abstract: A semiconductor device 1000 may include first and second switch elements 1000A and 1000B formed in first and second element forming regions 16a and 16b of a SOI layer 10a, respectively. The first and second switch elements 1000A and 1000B form a BiCMOS inverter circuit, and each includes a field effect transistor and a bi-polar transistor. A first p-type body region 50a is electrically connected to an n-type source region 120. The first p-type body region 50a is electrically connected to a first p-type base region 220. A second n-type body region 54a is electrically connected to a second n-type collector region 430. A p-type drain region 330 is electrically connected to a second p-type base region 420.

Abstract: A semiconductor device of a SOI (silicon on insulator) structure includes a P-type silicon support substrate, a first insulating layer formed on the semiconductor support substrate, and an SOI layer formed on the first insulating layer. A first hole is formed to penetrate through the semiconductor layer and the first insulating layer, and a P-type polysilicon layer is filled in the first hole so that the P-type polysilicon layer is electrically connected to the semiconductor support substrate. A second insulating layer is formed on the SOI layer. A second hole is formed to penetrate through the second insulating layer in alignment with the first hole, and an aluminum electrode is formed on the second insulating layer to fill the second hole, so that the aluminum electrode is electrically connected through the P-type polysilicon layer to the silicon support substrate. Thus, the potential of the silicon support substrate can be fixed through the aluminum electrode formed on the SOI layer side.

Abstract: A method for making silicon-on-sapphire transducers including the steps of forming a first silicon layer on a first side of a first sapphire wafer; bonding a second sapphire wafer to the first side of the first sapphire wafer such that the first silicon layer is interposed between the first and second sapphire wafers; reducing the thickness of the first sapphire wafer to a predetermined thickness; depositing a second silicon layer on a second surface of the first sapphire wafer, wherein the second surface of the first sapphire wafer is oppositely disposed from the first surface of the first sapphire wafer; bonding a silicon wafer to the second surface of the first sapphire wafer such that the second silicon layer is interposed between the first sapphire wafer and the silicon wafer, wherein the silicon wafer includes p+ regions indicative of a transducer structure and non-p+ regions; and, removing the non-p+ regions of the silicon wafer thus forming the transducer structure of p+ regions on

Abstract: The invention relates to device processing, packaging and interconnects that will yield integrated electronic circuitry of higher density and complexity than can be obtained by using conventional multi-chip modules. Processes include the formation of complex multi-function circuitry on common module substrates using circuit tiles of silicon thin-films which are transferred, interconnected and packaged. Circuit modules using integrated transfer/interconnect processes compatible with extremely high density and complexity provide large-area active-matrix displays with on-board drivers and logic in a complete glass-based modules. Other applications are contemplated, such as, displays, microprocessor and memory devices, and communication circuits with optical input and output.

Abstract: A semiconductor chip having a vertical current conduction structure of a high aspect ratio and high reliability: a semiconductor device, a circuit substrate, and an electronic apparatus each containing such semiconductor chips; and a method for producing them. A prehole (3) is formed in a silicon substrate (10) surface-oriented to a (100) face by laser beam irradiation. The prehole (3) is enlarged by anisotropic etching to thereby form a through-hole (4). An electrically insulating film is formed on an inner wall of the through-hole (4). An electrically conducting material is provided inside the insulating film to thereby form a metal bump (30).

Abstract: A SIMOX semiconductor structure is provided that may include a silicon substrate, a doped glass layer formed on the silicon substrate by ion implantation and a silicon layer formed on the silicon substrate. Ion implantation may form the doped glass layer to reduce the dislocation density of the silicon layer.

Abstract: A semiconductor device in which the potential of a conductive support substrate can be kept to be a predetermined potential, while an SOI substrate is used as a chip substrate, without adding a new step and providing a rear electrode, is provided. In a chip, on the main surface of a first Si substrate of a P-type, a SiO2 film and a second Si substrate of a P-type are laminated in this order. The chip has, in the second Si substrate, isolation trenches, an outermost isolation trench, a plurality of element forming regions isolated by these trenches, second element forming regions, a peripheral region, and a peripheral region connection wiring which connects a contact region of the peripheral region with a contact region connected with a predetermined potential, for example, a ground potential in the second element forming region surrounded by, for example, the isolation trench.

Abstract: The present invention relates to a method of thinning of a single-crystal silicon wafer so that the wafer has a final thickness lower than 80 &mgr;m.

Abstract: An integrated device having a substrate wherein a buried layer and an epitaxial region have been formed, and an isolation structure adapted to define a plurality of isolation wells for integrating the components of the integrated device therein, the isolation structure including plural dielectrically insulated regions or dielectric trenches being filled with a conductive material to form a plurality of contact regions to buried regions of the device, the buried regions including, in particular, the substrate and buried layer.

Abstract: The disclosed high voltage device includes a semiconductor substrate, and a first semiconductor layer formed between an underlying first insulating layer and an overlying second insulating layer buried within the semiconductor substrate. The high voltage device includes first and second drift regions formed over the second insulating layer in the semiconductor substrate and spaced apart from each other, an emitter impurity region formed in the first drift region, and a collector impurity region formed in the second drift region. The high voltage device further includes a second semiconductor layer adjacent to and insulated from the collector impurity region, and connected to the first semiconductor layer, and a third semiconductor layer adjacent to and insulated from the emitter impurity region, and connected to the first semiconductor layer.

Abstract: A method of fabricating a defect induced buried oxide (DIBOX) region in a semiconductor substrate utilizing an oxygen ion implantation step to create a stable defect region; a low energy implantation step to create an amorphous layer adjacent to the stable defect region, wherein the low energy implantation steps uses at least one ion other than oxygen; oxidation and, optionally, annealing, is provided. Silicon-on-insulator (SOI) materials comprising a semiconductor substrate having a DIBOX region in patterned or unpatterned forms is also provided herein.

Abstract: A semiconductor device includes two or more semiconductor elements provided on a semi-insulating substrate with a buffer layer and an interlevel film being interposed therebetween, an element isolating portion provided as a result of forming a groove between the two or more semiconductor elements through the buffer layer and the interlevel film so as to reach the semi-insulating substrate, and a protective film for protecting at least ends of the buffer layer in the vicinity of the element isolating portion.

Abstract: According to the present invention, a semiconductor device, and method for producing the same, is provided comprising: a resistance component formed in a component active region enclosed by a component separating-insulating layer on a semiconductor base; one pair of first diffusion layers containing a high concentration of impurities which are provided at both ends of the component active region; silicide layer adhering to a first diffusion layer; second diffusion layer containing a low concentration of impurities which is provided in the component active region between the pair of first diffusion layers; wherein a first diffusion layer and silicide layer comprise the terminal areas of the resistance component, and the second diffusion layer comprises a resistance member area of the resistance component.

Abstract: A diode is formed by forming a PN junction region 6 with a p region 5 formed on a buried oxide film 19 side and an n region 7 formed on the surface side in a surface silicon layer 3 which is isolated by the buried oxide film 19 of an SOI substrate 1, providing a lightly doped p region 33 on one end side of the PN junction region 6 and a lightly doped n region 31 on an other end side, forming a heavily doped p region 13 and a heavily doped n region 9 at the respective surface portions of the lightly doped p region 33 and the lightly doped n region 31 in such a manner as not to contact the PN junction region 6, and providing two metal plates which respectively connect to the heavily doped p region 13 and the heavily doped n region 9.

Abstract: An integrated circuit and method for making it is described. The integrated circuit includes an insulating layer, formed within a trench that separates conductive elements of a conductive layer, that has a low dielectric constant. The insulating layer is convertible at least in part into a layer that is resistant to a plasma that may be used for a photoresist ashing step or to a solvent that may be used for a via clean step. Preferably the insulating layer comprises a silicon containing block copolymer that is convertible at least in part into a silicon dioxide layer. The silicon dioxide layer protects the remainder of the insulating layer from subsequent processing, such as photoresist ashing and via clean steps.

Abstract: A dielectric isolated high voltage semiconductor device having an arrangement for extending a depletion layer of a main junction beyond an insulating layer containing an island to a semiconductor supporter by applying the same reverse biasing voltage to the supporter and the islands. That is, in the structure, an electrode is provided at the back surface of the supporter and connected to a main electrode of the selected island. The above-mentioned main junction is the pn junction to which the reverse biasing voltage for securing the withstand voltage of the semiconductor device is applied. The device is structured, also, with high impurity concentration regions for preventing a depletion layer, formed during a reverse biasing of the main junction of a circuit element of an island, from extending into adjacently disposed islands.

Abstract: A semiconductor device (120) is formed in a silicon-on-insulator (SOI) substrate (135). The semiconductor device (120) has a channel region (126) that is controlled by a gate structure (129). The channel region (126) has a doping profile that is essentially uniform where the channel region (126) is under the gate structure (129). This eliminates the parasitic channel region that is common with conventional field effect transistors (FETs) that are formed in SOI substrates. Consequently, the semiconductor device (120) of the present invention does not suffer from the "kink" problem that is common to conventional FET devices.

Abstract: A semiconductor device includes an insulating substrate; a plurality of pixel electrodes arranged in a matrix on the insulating substrate; first thin film transistors for individually driving the pixel electrodes; and driving circuits composed of second thin film transistors formed on the insulating substrate. In this semiconductor device, each of the first and second thin film transistors has a bottom-gate structure comprising a gate electrode patterned on the insulating substrate; a gate insulating film covering the gate electrode; and a semiconducting thin film having a channel region and a source/drain region, which is formed on the gate insulating film. Each of the second thin film transistors has a lightly doped region at least between a drain side highly doped region and the channel region.

Abstract: There is disclosed a semiconductor device formed on a sapphire substrate, for example, a blue LED of a double-hetero structure having a laminated structure which comprises a first cladding layer made of a first conductivity type gallium nitride based semiconductor, an active layer made of a gallium nitride based semiconductor into which impurity is not doped intentionally, and a second cladding layer made of a second conductivity type gallium nitride based semiconductor which being opposite to the first conductivity type on a sapphire substrate. A surface of the sapphire substrate is polished to have optical transmissivity of more than 60%.

Abstract: A semiconductor substrate which is optimum for a substrate for integrating a vertical power element and a control circuit element monolithically. A cavity 3 is formed between a dielectric layer 2 and a single crystal silicon substrate 4 in a control circuit element forming region 8, and junction planes 1a and 4a of single crystal silicon substrates 1 and 4 are joined together. Since bonding of regions where a vertical power element is formed is made with flat single crystal silicon planes, no void (non-bonded portion) is generated on the junction plane of the region where the vertical power element is formed. As a result, it is possible to realize a semiconductor device provided with perfect junction having electrical conductivity in a direction perpendicular to the junction interface.

Abstract: A method of semiconductor fabrication includes the steps of forming a dielectric layer on a first surface of a semiconductor wafer having a plurality of laterally distributed semiconductor devices selectively interconnected on the first surface and bonding a support substrate to the first surface of the semiconductor wafer on the dielectric layer to form a composite structure. A portion of the semiconductor wafer from a second surface which is opposite the first surface is removed and the second surface of the semiconductor wafer is processed. Processing of the second surface optionally includes the formation of isolation trenches electrically isolating the laterally distributed semiconductor devices.

Abstract: Semifinished products designed as composite bodies for electronic or opto-electronic semiconductor components are known. The composite bodies are made of a disk-shaped, transparent quartz glass substrate and a wafer made of a semiconductor material. The directly bonded surfaces of the quartz glass substrate and wafer are polished before being mutually bonded. In order to create a semifinished product that resists temperatures above 900.degree. C., such as those used to produce semiconductor circuits in industrially feasible times, without raising fears of a substantial reduction of the adhesive forces, chipping of the wafers away from each other or an undesirable deformation of the composite body, the substrate quartz glass is a synthetic quartz glass with at least 10.sup.14.0 poise viscosity at 950.degree. C. which does not fall below 10.sup.12 poise at 1050.degree. C.