Abstract: A silicon-on-insulator device has a localized biasing structure formed in the insulator layer of the SOI. The localized biasing structure includes a patterned conductor that provides a biasing signal to distinct regions of the silicon layer of the SOI. The conductor is recessed into the insulator layer to provide a substantially planar interface with the silicon layer. The conductor is connected to a bias voltage source. In an embodiment, a plurality of conductor is provided that respectively connected to a plurality of voltage sources. Thus, different regions of the silicon layer are biased by different bias signals.

Abstract: A method for controlled growth of silicon carbide and structures produced by the method are disclosed. A crystal of silicon carbide (SiC) can be grown by placing a sacrificial substrate in a growth zone with a source material. The source material may include a low-solubility impurity. SiC is then grown on the sacrificial substrate to condition the source material. The sacrificial substrate is then replaced with the final substrate, and SiC is grown on the final substrate. A single crystal of silicon carbide is produced, wherein the crystal of silicon carbide has substantially few micropipe defects. Such a crystal may also include a substantially uniform concentration of the low-solubility impurity, and may be used to make wafers and/or SiC die.

Abstract: A TFT (Thin Film Transistor) is provided in which a hydrogen feeding layer is able to be formed in a position where diffusing distance of hydrogen can be made short without causing an increase in photolithography processes. In the TFT, the hydrogen feeding layer to diffuse hydrogen into a dangling bond existing at an interface between a polycrystalline silicon thin film and a gate insulating film is formed in a position between the gate insulating film and a gate electrode. According to this configuration, diffusing distance of hydrogen at a period of time during hydrogenation can be made short and the hydrogenation process can be sufficiently performed without taking time in heat treatment.

Abstract: A method for forming a protection diode utilizes processing operations and materials used in the formation of the CMOS integrated circuit device and provides a protection diode used in CMOS integrated circuit devices to direct charged particles to benign locations and prevent damage to the devices. The protection diode includes a well region of a first conductivity type formed in a surface of a semiconductor substrate, a heavily doped P-type impurity region disposed within the well region, a heavily doped N-type impurity region disposed within the well region and an STI structure interposed therebetween. A top surface of the STI structure extends above the surface. A silicide resistant block-out layer is formed over the STI structure and extends laterally beyond the STI structure, covering any counterdoped sections that may undesirably be formed in the substrate adjacent the STI structure during implantation operations.

Abstract: A nonvolatile semiconductor memory includes a transistor, one or two resistance-change portions, and one or two charge accumulation portions. The transistor has a control electrode, first main electrode region, and second main electrode region. Each resistance-change portion is of a second conductivity type having impurity concentration lower than that of the first and second main electrode regions. The charge-accumulation portions are provided on the associated resistance-change portions. Each charge accumulation portion has an insulating layer, and is capable of accumulating charge.

Abstract: The present invention discloses a method for manufacturing a flash memory device which can minimize a hole current by impurity diffusion of floating gates, obtain a sufficient capacitance for a cell operation by increasing a breakdown voltage, and improve retention properties of a flash memory cell, by filing up an impurity on the interface between an oxide film and a polysilicon film, by forming the oxide film on the polysilicon film used as the floating gates, doping an impurity into the oxide film, and annealing the oxide film.

Abstract: The present invention pertains to forming a transistor in the absence of hydrogen, or in the presence of a significantly reduced amount of hydrogen. In this manner, a high-k material can be utilized to form a gate dielectric layer in the transistor and facilitate device scaling while mitigating defects that can be introduced into the high-k material by the presence of hydrogen and/or hydrogen containing compounds.

Abstract: A method of fabricating a TFT includes a step of forming an impurity region for a source and a drain by simultaneously implanting and activating impurity ions. More particularly, the present invention includes the steps of forming a gate insulating layer and a gate on a predetermined and selected portion of an active layer, forming an excited region in the exposed portion of the active layer by implanting hydrogen ions to the active layer by using the gate as a mask, and forming an impurity region by implanting impurity ions heavily to the excited region which remains in an excited state.

Abstract: A p-channel field-effect transistor is formed on a semiconductor substrate. The transistor has an n-doped gate electrode, a buried channel, a p-doped source and a p-doped drain. The transistor is fabricated by a procedure in which, after an implantation for defining an n-type well, an oxidation is performed to form a gate-oxide layer and n-doped polysilicon is subsequently deposited. The latter is doped with boron or boron fluoride particles either in situ or by a dedicated implantation step. In a thermal process, the boron acceptors penetrate through the oxide layer into the substrate of the n-type well, where they form a p-doped zone, which serves for counter doping and sets the threshold voltage. This results in a steep profile that permits a shallow buried channel. The control of the number particles penetrating through the oxide layer is achieved by nitriding the oxide layer in an N2O atmosphere.

Abstract: A method of forming a retrograde well in a transistor is provided. A transistor structure having a substrate, a gate, and a gate oxide layer between the substrate and the gate is formed. The substrate includes a channel region located generally below the gate. A first dopant is implanted into the channel region. A second dopant is implanted into the substrate to form a doped source region and a doped drain region. A third dopant is implanted into the gate oxide layer. A source/drain anneal is performed to form a source and a drain in the doped source region and the doped drain region, respectively. The source/drain anneal causes a portion of the first dopant in the channel region to be attracted by the third dopant into the gate oxide layer.

Abstract: A semiconductor arrangement including: a substrate having a substrate layer (13) with an upper and lower surface, the substrate layer (13) being of a first conductivity type; a first buried layer (12) in the substrate, extending along said lower surface below a first portion of said upper surface of said substrate layer (13), and a second buried layer (12) in the substrate, extending along said lower surface below a second portion of said upper surface of said substrate layer (13); a first diffusion (26) in said first portion of said substrate layer (13), being of a second conductivity type opposite to said first conductivity type and having a first distance to said first buried layer (12) for defining a first breakdown voltage between said first diffusion (26) and said first buried layer (12); a second diffusion (45) in said second portion of said substrate layer (13), being of said second conductivity type and having a second distance to said second buried layer (12) for defining a second breakdown volta

Abstract: A method is disclosed for forming a semiconductor wafer having a strained Si or SiGe layer on an insulator layer. The method produces a structure having a SiGe buffer layer between the insulator layer and the strained Si or SiGe layer, but eliminates the need for Si epitaxy after bonding. The method also eliminates interfacial contamination between strained Si and SiGe buffer layer, and allows the formation of Si/SiGe layers having a total thickness exceeding the critical thickness of the strained Si layer.

Abstract: A silicon-containing insulation film having high mechanical strength is formed on a semiconductor substrate by (a) introducing a reaction gas comprising (i) a source gas comprising a silicon-containing hydrocarbon compound containing cross-linkable groups, (ii) a cross-linking gas, and (iii) an inert gas, into a reaction chamber where a substrate is placed; (b) applying radio-frequency power to create a plasma reaction space inside the reaction chamber; and (c) controlling a flow of the reaction gas and an intensity of the radio-frequency power.

Abstract: The present invention relates generally to a method of improving the performance of solid state devices, and specifically provides methods for passivating a semiconductor surfaces with a monolayer of passivating material.

Abstract: In a silicon layer formed on an insulator layer, a lattice defect region is formed to be adjacent to a channel region and source/drain regions, and the lower part of the channel region functions as a high-concentration channel region. The holes of hole-electron pairs generated in the channel region are eliminated by recombination in the lattice defect region, thereby suppressing the bipolar operation resulting from the accumulation of holes and increasing the source/drain breakdown voltage. The threshold value of a parasitic transistor is increased by the high-concentration channel region so as to reduce the leakage current in the OFF state. Alternatively, the holes may be moved to the source region to disappear therein by providing, instead of the lattice defect region, a high-concentration diffusion layer constituting and operating as a pn diode between the channel and source regions.

Abstract: In producing a semiconductor device such as a thin film transistor (TFT), a silicon semiconductor film is formed on a substrate having an insulating surface, such as a glass substrate, and then a silicon nitride film is formed on the silicon semiconductor film. After that, a hydrogen ion, fluorine ion, or chlorine ion is introduced into the silicon semiconductor film through the silicon nitride film, and then the silicon semiconductor film into which an ion is introduced is heated in an atmosphere containing hydrogen, fluorine, chlorine or these mixture, to neutralize dangling bonds in the silicon semiconductor film and reduce levels in the silicon semiconductor film.

Abstract: A process for providing a semiconducting device including the steps of depositing a semiconducting layer onto a substrate by means of heating a gas to a predetermined dissociation temperature so that the gas dissociates into fractions, whereby those fractions subsequently condense on the substrate to build up a semiconducting layer.

Abstract: Silicon oxide films which are good as gate insulation films are formed by subjecting a silicon oxide film which has been formed on an active layer comprising a silicon film by means of a PVD method or CVD method to a heat treatment at 300-700° C. in a dinitrogen monoxide atmosphere, or in an NH3 or N2H4 atmosphere, while irradiating with ultraviolet light, reducing the hydrogen and carbon contents in the silicon oxide film and introducing nitrogen into the boundary with the silicon film in particular. Furthermore, silicon oxide films which are good as gate insulating films have been formed by subjecting silicon oxide films which have been formed on an active layer comprising a silicon film by means of a PVD method or CVD method to a heat treatment at 300-700° C. in an N2O atmosphere (or hydrogen nitride atmosphere) while irradiating with ultraviolet light, and then carrying out a heat treatment at 300-700° C.

Abstract: A MOS structure processed to have a semiconductor-dielectric interface that is passivated to reduce the interface state density. An example is a MOSFET having a gate dielectric on which an electrode is present that is substantially impervious to molecular hydrogen, but sufficiently thin to be pervious to atomic hydrogen, enabling atomic hydrogen to be diffused therethrough into an underlying semiconductor-dielectric interface. Atomic hydrogen diffusion can be achieved by subjecting such an electrode to hydrogen plasma, forming the electrode of an aluminum-tungsten alloy in the presence of hydrogen, and implanting atomic hydrogen into the electrode. The latter two techniques are each followed by an anneal to cause the atomic hydrogen to diffuse through the electrode and into the semiconductor-dielectric interface.

Abstract: A wafer bonding method of forming silicon-on-insulator comprising integrated circuitry includes nitridizing at least a portion of an outer surface of silicon of a device wafer. After the nitridizing, the device wafer is joined with a handle wafer. A method of forming silicon-on-insulator comprising integrated circuitry includes nitridizing an interface of the silicon comprising layer of silicon-on-insulator circuitry with the insulator layer of the silicon-on-insulator circuitry. After the nitridizing, a field effect transistor gate is formed operably proximate the silicon comprising layer. Other methods, are disclosed. Integrated circuitry is contemplated regardless of the method of fabrication.

Abstract: This invention relates to a method of manufacturing an SOI wafer having a low HF defect density using annealing in a reducing atmosphere. An SOI substrate is annealed in a reducing atmosphere at a temperature lower than the melting point of single-crystal silicon. To prevent any HF defects, a holding tool having a surface formed from silicon is used as a holding tool for holding the SOI substrate.

Abstract: Described are preferred processes for conditioning semiconductor devices with deuterium to improve operating characteristics and decrease depassivation which occurs during the course of device operation. Also described are semiconductor devices which can be prepared by such processes.

Abstract: An electronic device manufacturing equipment such as for manufacturing liquid crystal display devices containing semiconductor integrated circuits. The equipment includes a protective resistive layer such as with a thickness d (&mgr;m) and a surface resistance of (55/d)2×(1×105 to 1×108) ohm/square disposed on a working surface of the equipment between the electronic device and the working surface. In broader terms the present invention is also a method for protecting sensitive electronic components of electronic devices during manufacturing from damage due to electrostatic charges by placing a resistive layer having a thickness d (&mgr;m) and a surface resistance of (55/d)2×(1×105 to 1×108) ohm/square between the equipment surface and the electronic device.

Abstract: A cell plate electrode is shared between storage capacitors of memory cells incorporated in a semiconductor dynamic random access memory device of the type having the storage capacitors over bit lines, and slits are formed in the cell plate electrode in such a manner that the boundaries between channel regions and gate oxide layers are horizontally spaced from the outer periphery of the cell plate electrode and the slits by distances equal to or less than a critical distance determined on the basis of a diffusion length of hydrogen in an inter-level insulating layer, thereby causing the hydrogen to surely reach the boundaries for reducing the density of surface state.

Abstract: A semiconductor integrated circuit according to the present invention comprises a synchronous SRAM, a signal generation circuit generating a chip selection signal, a clock signal etc. supplied to the synchronous SRAM, a voltage set circuit setting the voltage of a system power supply line and a controller controlling the signal generation circuit and the voltage set circuit. When setting the synchronous SRAM in a power down mode, the chip selection signal is set in a nonselective state and the power supply voltage of the system power supply line is stepped down to a standby potential. Thus, the synchronous SRAM enters a standby state having extremely low power consumption.

Abstract: In producing a semiconductor device such as a thin film transistor (TFT), a silicon semiconductor film is formed on a substrate having an insulating surface, such as a glass substrate, and then a silicon nitride film is formed on the silicon semiconductor film. After that, a hydrogen ion, fluorine ion, or chlorine ion is introduced into the silicon semiconductor film through the silicon nitride film, and then the silicon semiconductor film into which an ion is introduced is heated in an atmosphere containing hydrogen, fluorine, chlorine or these mixture, to neutralize dangling bonds in the silicon semiconductor film and reduce levels in the silicon semiconductor film.

Abstract: A transistor structure fabricated on thin SOI is disclosed. The transistor on thin SOI has gated n+ and p+ junctions, which serve as switches turning on and off GIDL current on the surface of the junction. GIDL current will flow into the floating body and clamp its potential and can thus serve as an output node. The transistor can function as an inverter. The body (either n-well or p-well) is isolated from the n+ or P+ “GIDL switches” by a region of opposite doping type, i.e., p-base and n-base. The basic building blocks of logic circuits, e.g., NAND and NOR gates, are easily implemented with such transistors on thin SOI wafers. These new transistors on thin SOI only need contacts and metal line connections on the Vcc and Vss. The connection of fan-outs (between the output and input) can be implemented by capacitor coupling. The transistor structure and operation is useful for highperformance, low-voltage, and low-power VLSI circuits on SOI wafers.

Abstract: The method for fabricating a semiconductor device comprises an insulation film forming step of forming an insulation film 12 on a semiconductor substrate 10, a semiconductor layer forming step of forming a semiconductor layer 14 on the insulation film 12, and an impurity implanting step of implanting an impurity containing hydrogen into the semiconductor layer 14, the method being characterized by further comprising a fluorine implanting step of implanting fluorine in at least the insulation film 12. The dangling bonds of the insulation film can be bonded with the fluorine, whereby the fluorine, which has higher bonding energy with respect to silicon of the insulation film than hydrogen, is never dissociated from the silicon of the insulation film in the following heat treatments, BT stress test, etc. Accordingly, an interface state density in the interface between the insulation film and the semiconductor substrate can be depressed low, and a fixed charge in the insulation film can be depressed small.

Abstract: Disclosed are methods and systems for etching dielectric layers in a high density plasma etcher. A method includes providing a wafer having a photoresist mask over a dielectric layer in order to define at least one contact via hole or open area that is electrically interconnected down to the silicon substrate of the wafer. The method then proceeds to inserting the wafer into the high density plasma etcher and pulsed application a TCP power source of the high density plasma etcher. The pulsed application includes ascertaining a desired etch performance characteristic, which includes photoresist selectivity and etch rate which is associated with a continuous wave application of the TCP source. Then, selecting a duty cycle of the pulsed application of the TCP source and scaling a peak power of the pulsed application of the TCP source in order to match a cycle-averaged power that would be delivered by the continuous wave application of the TCP source.

Abstract: A method of processing wafers containing a gate oxide assembly (10) is disclosed that reduces gate oxide damage during wafer production due to damage caused by charging. The method comprises creating an oxide gate assembly (10) on a silicon layer (11) in a production line chamber followed by the deposition of a polysilicon layer (22). Following the creation of the gate oxide assembly (10) a pressure of at least 1.2 Torr is maintained while lowering the power within the production line chamber. The invention can be used with a gate oxide layer (16) of less than 1000 angstroms.

Abstract: A method for fabricating a high-density and high-reliability EEPROM device includes providing a semiconductor substrate having both an EEPROM cell region, and a peripheral MOS transistor region. A gate oxide layer is formed to overlie the peripheral MOS transistor region and the EEPROM cell region. A tunnel oxide region is formed to overlie a portion of the EEPROM cell region. Then, a polycrystalline silicon layer is formed to overlie both the gate oxide layer and the tunnel oxide region. A deuterium annealing process is then carried out to anneal the gate oxide layer and the tunnel oxide region. The polycrystalline silicon layer is patterned to form numerous gate electrodes including gate electrodes for peripheral transistors, floating-gate transistors, and read and write transistors in the EEPROM cell.

Abstract: SOI FETs include an electrically insulating substrate, a semiconductor region on the electrically insulating substrate, a field effect transistor having source, drain and channel regions in the semiconductor region and a metal silicide region between the electrically insulating substrate and the semiconductor region. The metal silicide region (e.g., TiSi.sub.2) forms non-rectifying junctions with the source and channel regions of the field effect transistor so that holes accumulated in the channel region (upon impact ionization) can be readily transported to the source region (and contact thereto) via the metal silicide layer and recombination of the holes with electrons in the source region can be carried out with high efficiency. The metal silicide region ohmically contacts the source and channel regions, but does not form a junction with the drain region of said field effect transistor.

Abstract: An interconnect track connects, on several metallization levels, an insulated gate of a transistor to a discharge diode within an integrated circuit. The interconnect track comprises a first track element extending under the highest metallization level, having a first end connected to the gate and having a length greater than a predetermined critical length. This first track element includes an interrupted track portion at a site a first distance less than the critical length away from the first end. This point is compatible with the placement of the metallization level above, and extends between two insulating layers on the same metallization level. The two branches of the interrupted portion are mutually connected by a metallic filling contact which also extends in the insulating support layer of the metallization level immediately above that containing the interrupted track portion.

Abstract: A semiconductor manufacturing process comprising providing a semiconductor substrate, forming a gate dielectric on an upper surface of the semiconductor substrate, forming a conductive gate on an upper surface of the gate dielectric, forming a first pair of spacer structures on the first and second sidewalls of the conductive gate, introducing a first source impurity distribution into the semiconductor substrate, forming a second pair of spacer structures on respective exterior sidewalls on the first pair of spacer structures, and introducing a drain impurity distribution into the detached drain region of the semiconductor substrate. The semiconductor substrate includes a channel region laterally displaced between a first source region and a detached drain region. The conductive gate includes a first and a second sidewall. Exterior sidewalls of the first pair of spacer structures are displaced from the first and second sidewalls of the conductive gate by a source displacement.

Abstract: Reduction of gate-induced-drain-leakage in metal oxide semiconductor (MOS) devices is achieved by performing an anneal in a non-oxidizing ambient. In one embodiment, the anneal is performed in a argon and/or ammonia ambients after gate sidewall oxidation that forms the spacers.

Abstract: A process for manufacturing a non-volatile semiconductor memory device by forming a tunnel dielectric film, a floating gate electrode, an interlayer capacitive film and a control gate electrode successively on a semiconductor substrate includes introducing nitrogen atoms into at least one of an interface between the floating gate electrode and the interlayer capacitive film and an interface between the interlayer capacitive film and the control gate electrode.

Abstract: A method for forming a gate dielectric (14b) begins by providing a substrate (12). A high K dielectric layer (14a) is deposited overlying the substrate (12). The dielectric layer (14a) contains bulk traps (16) and interface traps (18). A polysilicon gate electrode (20) is then patterned and etched overlying the gate dielectric (14a) whereby the plasma etching of the gate electrode (20) results in substrate plasma damage (22). A post gate wet oxidation process is performed between 750.degree. C. and 850.degree. C. to reduce plasma etch damage and trap sites (16, 18) in order to provide an improved gate dielectric (14b). Source and drain electrodes (30) are then formed within the substrate and laterally adjacent the gate electrode (20) to form a transistor device having more consistent threshold voltages, improved subthreshold slope operation, reduced gate to channel leakage, and improved speed of operation.

Abstract: Silicon oxide films which are good as gate insulation films are formed by subjecting a silicon oxide film which has been formed on an active layer comprising a silicon film by means of a PVD method or CVD method to a heat treatment at 300-700.degree. C. in a dinitrogen monoxide atmosphere, or in an NH.sub.3 or N.sub.2 H.sub.4 atmosphere, while irradiating with ultraviolet light, reducing the hydrogen and carbon contents in the silicon oxide film and introducing nitrogen into the boundary with the silicon film in particular. Furthermore, silicon oxide films which are good as gate insulating films have been formed by subjecting silicon oxide films which have been formed on an active layer comprising a silicon film by means of a PVD method or CVD method to a heat treatment at 300-700.degree. C. in an N.sub.2 O atmosphere (or hydrogen nitride atmosphere) while irradiating with ultraviolet light, and then carrying out a heat treatment at 300-700.degree. C. in a hydrogen nitride atmosphere (N.sub.

Abstract: A semiconductor process for forming a gate electrode of an MOS transistor. A gate dielectric is deposited on an upper surface of a semiconductor substrate. A dielectric constant of the gate dielectric layer is in the range of approximately 25 to 300. A thickness of the gate dielectric is in the range of approximately 50 to 1,000 angstroms. A conductive gate layer is then formed on the gate dielectric layer. A first nitrogen distribution is then introduced into the gate dielectric layer. The introduction of the first nitrogen distribution is typically accomplished by implanting a first nitrogen bearing species into the gate dielectric layer. Ideally, a peak impurity concentration of the first nitrogen distribution is located at an interface between the semiconductor substrate and the gate dielectric layer. Thereafter, a second nitrogen distribution is introduced into the gate dielectric layer.

Abstract: In producing a semiconductor device such as a thin film transistor (TFT), a silicon semiconductor film is formed on a substrate having an insulating surface, such as a glass substrate, and then a silicon nitride film is formed on the silicon semiconductor film. After that, a hydrogen ion, fluorine ion, or chlorine ion is introduced into the silicon semiconductor film through the silicon nitride film, and then the silicon semiconductor film into which an ion is introduced is heated in an atmosphere containing hydrogen, fluorine, chlorine or these mixture, to neutralize dangling bonds in the silicon semiconductor film and reduce levels in the silicon semiconductor film.

Abstract: A transistor fabrication process is provided which derives a benefit from having barrier atoms incorporated in a lateral area under a gate oxide of the transistor in close proximity to the drain. To form the transistor, a gate oxide layer is first grown across a silicon-based substrate. A polysilicon layer is then deposited across the gate oxide layer. Portions of the polysilicon layer and the oxide layer are removed to form a gate conductor and gate oxide, thereby exposing source-side and drain-side junctions within the substrate. An LDD implant is performed to lightly dope the source-side and drain-side junctions. An etch stop material may be formed upon opposed sidewall surfaces of the gate conductor, the upper surface of the gate conductor, and the source-side and drain-side junctions. Spacers may then be formed laterally adjacent the etch stop material located upon sidewall surfaces of the gate conductor.

Abstract: In a CMOS device uses a thin oxide film as a gate dielectric film, gate electrode plasma etching frequently induces gate dielectric damage. This invention discloses a process which can form a damage free gate dielectric even though there is plasma nonuniformity during gate electrode etching. In this invention, a thin polysilicon layer is formed on the gate dielectric (gate oxide) layer and a thin oxide layer (not gate oxide) is formed on the thin polysilicon layer. The thin oxide layer (not gate oxide) is then patterned and etched to expose portions of the thin polysilicon layer. A thick polysilicon layer used to form the gate electrode is subsequently deposited. The thick polysilicon layer contacts the exposed portion of the underlying thin polysilicon layer, but is otherwise separated from the thin polysilicon layer by the thin oxide. The thin polysilicon layer is patterned and etched using a plasma etching process. The thin oxide (not the gate oxide) acts as an etching stop.

Abstract: The present invention discloses a method of fabricating flash memory cell for use in semiconductor memories. A nitrogen implantation step is added in the process to increase the performance of the device. The nitrogen implanted tunnel oxide exhibits a much higher electron conduction efficiency than the prior art tunnel oxides in both injection polarities. The value of charge-to-breakdown voltage of the nitrogen implanted tunnel oxide is also much larger than the narrow tunnel oxide. In addition, the electron trapping rate of the nitrogen implantation tunnel oxide is very small even under a very large electron fluence stressing (100 C/cm.sup.2).

Abstract: A non-volatile memory device is fabricated having enhanced charge retention capability. Enhanced charge retention is achieved upon the floating gate of the non-volatile memory device. The floating gate maybe can configured as a stacked or non-stacked pair of polysilicon conductors. In either instance, negative charge programmed upon the floating gate is retained by reducing the presence of positively charged atoms within dielectrics overlying the floating gate conductor. Moreover, diffusion avenues of the positively charged hydrogen are reduced by maintaining a prevalence of relatively strong bond locations within the overlying dielectric layers. Thus, origination of positively charged atoms, such as hydrogen, from those bonds are substantially prevented by processing the hydrogen-containing dielectrics at relatively low temperatures and further processing any subsequent dielectrics and/or conductors overlying the floating gate at relatively low temperatures.

Abstract: A method of forming a bottom gated TFT includes, a) providing a transistor gate relative to a substrate which projects outward thereof; b) providing a dielectric layer over the gate; c) providing a TFT layer of semiconductive material over the dielectric layer; the thin film transistor layer comprising a source area, a channel area, a drain area, and a drain offset area; d) providing a masking layer over the TFT layer; e) anisotropically etching the masking layer to define a masking sidewall spacer laterally adjacent the transistor gate over the drain offset area and leave the channel area outwardly exposed; f) with the masking sidewall spacer in place, implanting a conductivity enhancing impurity of a first type into the thin film channel area to provide a thin film channel region; and g) masking the channel area and the drain offset area while implanting conductivity enhancing impurity of a second type into the thin film source and drain areas to define thin film source and channel regions.

Abstract: A process is provided in which silicon thin film transistors fabricated with polycrystalline silicon, silicon oxide, and silicon conductive layers are exposed to microwave plasmas containing water vapor and to subsequent annealing steps to bring about an improvement in the ratio of device drain current in the conductive state to that in the non-conductive state, and a lower device subthreshold voltage swing.

Abstract: A semiconductor device is described, incorporating electron traps at the interface between a semiconductor substrate and a gate dielectric layer of an insulated gate field effect transistor, such device being capable of retaining charge in the electron traps for a certain time, allowing volatile memory circuits to be produced wherein each cell occupies only the area required for a single transistor.

Abstract: This invention is a method for forming fluorine-doped silicate glass having low concentrations of free fluorine atoms. A first embodiment of the invention provides simultaneous deposition of the fluorine-doped glass and scavenging of free fluorine atoms from the surface of the depositing material. A silicon-containing compound, an oxidizer, a fluorine containing compound and a hydrogen-containing gas are introduced into a plasma chemical vapor deposition chamber. A fluorine-doped glass layer having low concentrations of free fluorine atoms deposits. A second embodiment of the invention provides for scavenging of free fluorine atoms from an already-deposited fluorine-doped glass layer by annealing the layer in a forming gas containing hydrogen. The hydrogen gas diffuses into the deposited film and reacts with free fluorine atoms. The hydrogen fluoride so formed migrates through the matrix to the surface of the deposited film, where it is released into the ambient.

Abstract: A process for fabricating films improved in interface characteristics, which comprises depositing an oxide insulating film by sputtering under an irradiation of a light in an atmosphere comprising an oxidative gas at an amount larger than that of an inactive gas is disclosed. Particularly, a light having a wavelength of 300 nm or shorter is used for the irradiation.

Abstract: In producing a semiconductor device such as a thin film transistor (TFT), a silicon semiconductor film is formed on a substrate having an insulating surface, such as a glass substrate, and then a silicon nitride film is formed on the silicon semiconductor film. After that, a hydrogen ion, fluorine ion, or chlorine ion is introduced into the silicon semiconductor film through the silicon nitride film, and then the silicon semiconductor film into which an ion is introduced is heated in an atmosphere containing hydrogen, fluorine, chlorine or these mixture, to neutralize dangling bonds in the silicon semiconductor film and reduce levels in the silicon semiconductor film.