Abstract: A method of forming an electronic component package includes coupling a first surface of an electronic component to a first surface of a first dielectric strip, the electronic component comprising bond pads on the first surface; forming first via apertures through the first dielectric strip to expose the bond pads; and filling the first via apertures with an electrically conductive material to form first vias electrically coupled to the bond pads. The bond pads are directly connected to the corresponding first vias without the use of a solder and without the need to form a solder wetting layer on the bond pads.

Abstract: A semiconductor device is produced using a lead frame whose size is smaller than a prescribed center area of a semiconductor chip surrounded by its bonding pads, which are connected with electrodes supported by electrode supports and interconnected with outer frames and an intermediate frame of the lead frame via bonding wires. A series of projections and hollows are formed on the outer frames, wherein the electrode supports are interconnected with the hollows of the outer frames respectively. The semiconductor chip combined with the lead frame, is integrally enclosed in a resin under the condition where only the electrode surfaces are exposed to the exterior, thus forming a resin package. Then, the electrode supports locating the electrodes are cut out and partially removed, so that the electrodes are made electrically independent from each other.

Abstract: A method (300) for fabricating a lead frame (100), comprising forming a plurality of external leads (122) in a lead frame material (108), plating a metal (222) on all surfaces of the lead frame material (108), and subsequently forming a plurality of internal leads (124) in the lead frame material (108). The lead frame material (108) may comprise of a portion of a contiguous metal sheeting (204) rolled upon a first coil (202), wherein the contiguous metal sheeting (204) is fed into an external lead stamping apparatus (206), thus forming the external leads (122), and rolled onto a second coil (215). The portion is fed into a plating apparatus and plated with the metal (222), and rolled onto a third coil (218) prior to forming the plurality of internal leads (124). The third coil (218) can be unrolled into an internal lead stamping apparatus (226), thus forming the internal leads (124) of a lead frame (100).

Abstract: An electronic component and a method for making an electronic component are disclosed. The electronic component has a silicon package. The silicon package has a recess formed thereon in which a conductive region is placed. A bare die electronic device is disposed in the recess. The device has a top, a bottom, sides and a plurality of terminals, including a non-top terminal. The non-top terminal is electrically coupled to the conductive region. The electronic component is constructed by first creating a recess in a silicon wafer to a depth substantially equal to the first dimension of the bare die electronic device. A conductive material is applied to the recess. The electronic device is inserted into the recess so that the bottom terminal is coupled to the conductive material. A dielectric or other planarizing material is applied into the recess. Top and bottom contacts are then applied to form the electronic component so that it may be used as a ball grid array package.

Abstract: During fabrication of a mask read-only memory (ROM) device, a dielectric layer is grown on a substrate. Strip-stacked layers are formed on the dielectric layer, with each strip-stacked layer including a polysilicon and a silicon nitride layer. Source/drain regions are formed in the substrate between the strip-stacked layers, and spacers are then deposited between the strip-stacked layers. The strip-stacked layers are patterned into gates, which are disposed over every code position, with silicon nitride pillars being disposed on the gates. Additional spacers are formed on gate sidewalls. The silicon nitride pillars are removed, exposing the gates. A mask is then formed to cover active code positions, in accordance with the desired programming code. Insulating layers are then deposited through the mask onto the exposed gates. When the mask is removed, word lines are formed, interconnecting the gates without the insulating layers.

Abstract: To provide a method for manufacturing an electro-optical substrate having high reliability with high yield. The method for manufacturing an electro-optical substrate including a composite base plate obtained by joining a support plate to a semiconductor plate having single-crystal silicon precursor layer (semiconductor precursor layer) can include a step of forming a light-shielding layer, having a predetermined pattern, on the support plate, a step of forming an insulating layer on the light-shielding layer having the predetermined pattern, a step of providing semiconductor layers on the insulating layer, a step of oxidizing parts of the semiconductor layers to form oxide layers, and a step of removing the oxide layers. The oxide layers can have a thickness smaller than that of the insulating layer.

Abstract: There is provided a technique to form a single crystal semiconductor thin film or a substantially single crystal semiconductor thin film. An amorphous semiconductor thin film is irradiated with ultraviolet light or infrared light, to obtain a crystalline semiconductor thin film (102). Then, the crystalline semiconductor thin film (102) is subjected to a heat treatment at a temperature of 900 to 1200° C. in a reducing atmosphere. The surface of the crystalline semiconductor thin film is extremely flattened through this step, defects in crystal grains and crystal grain boundaries disappear, and the single crystal semiconductor thin film or substantially single crystal semiconductor thin film is obtained.

Abstract: In one embodiment a transistor is formed with a gate structure having an opening in the gate structure. An insulator is formed on at least sidewalls of the opening and a conductor is formed on the insulator.

Abstract: A method of manufacturing a thin film transistor is described. A polysilicon island is formed over a substrate. A gate insulating layer is formed over the substrate to cover the polysilicin island. A gate is formed on the gate insulating layer above the polysilicon island. A passivation layer is formed over the substrate to cover the gate and the gate insulating layer. An ion implanting process is carried out to form a source/drain in the polysilicon island beside the gate, wherein a region between the source and the drain is a channel. After the first passivation layer is removed, a patterned dielectric layer is formed over the substrate, wherein the dielectric layer exposes a portion of the source/drain. A source/drain conductive layer is formed over the dielectric layer and is electrically connected to the source/drain.

Abstract: A silicon-on-insulator (SOI) device structure 100 formed using a self-aligned body tie (SABT) process. The SABT process connects the silicon body of a partially depleted (PD) structure to a bias terminal. In addition, the SABT process creates a self-aligned area of silicon around the edge of the active areas, as defined by the standard transistor active area mask, providing an area efficient device layout. By reducing the overall gate area, the speed and yield of the device may be increased. In addition, the process flow minimizes the sensitivity of critical device parameters due to misalignment and critical dimension control. The SABT process also suppresses the parasitic gate capacitance created with standard body tie techniques.

Abstract: A method for manufacturing a semiconductor device including forming a gate electrode over a substrate; forming a pate insulating film over the pate electrode and over the substrate; forming a semiconductor film on the gate insulating film; providing the semiconductor film with a metal element; crystallizing the semiconductor film provided with the metal element; doping an element which is used for gettering into a portion of the crystallized semiconductor film; and heating the crystallized semiconductor film whereby the metal element contained in a channel region of the semiconductor film is gettered by the portion.

Abstract: A polysilicon thin film fabrication method is provided, in which a heat-absorbing layer is used to provide sufficient heat for grain growth of an amorphous silicon thin film, and an insulating layer is used to isolate the heat-absorbing layer and the amorphous silicon thin film. A regular heat-conducting layer is used as a cooling source to control the crystallization position and grain size of the amorphous silicon thin film. Therefore, the amorphous silicon thin film can crystallize into a uniform polysilicon thin film, and the electrical characteristics of the polysilicon thin film can be stably controlled.

Abstract: A semiconductor sensor device is formed using MEMS technology by placing a thin layer of single-crystal silicon, which includes semiconductor devices, over a cavity, which has been formed in a semiconductor material. The thin layer of single-crystal silicon can be formed by forming the semiconductor devices in the top surface of a single-crystal silicon wafer, thinning the silicon wafer to a desired thickness, and then dicing the thinned wafer to form silicon layers of a desired size. The MEMS device can be used to implement a pressure sensor, microphone, temperature sensor, and a joystick.

Abstract: A method for reducing non-uniformity or topography variation between a cell array area and a peripheral circuitry area is used in a process for manufacturing semiconductor integrated non-volatile memory devices, wherein an intermediate stack of multiple layers is provided during the manufacturing steps of gates structures in both the array and circuitry areas. A thin stack comprising at least a thin dielectric layer and a third conductive layer is provided over a second conductive layer before the step of defining the control gate structures in the array and the single gates in the peripheral circuitry. This intermediate stack of multiple layers is used in order to compensate for thickness differences between the dual gate structures in the array and the single gate transistors in the peripheral circuitry.

Abstract: Exemplary embodiments discourage or prevent impurities from mixing in a film of a semiconductor layer in a manufacturing process of a semiconductor device. A manufacturing process of a semiconductor device includes first forming a semiconductor layer, second removing hydrogen from inside the semiconductor layer, and third terminating by combining elements such as hydrogen with a surface of the semiconductor layer through exposure to hydrogen plasma and the like. At least the second removing and the third terminating are consecutively performed under an environment isolated from air. According to this process, it is possible to prevent or discourage impurities contained in air and the like from combining on the surface of the semiconductor film. It is possible to discourage or prevent impurities from mixing (diffusing) in the semiconductor layer in crystallization through irradiation by light following the third terminating.

Abstract: According to some embodiments, methods of fabricating a complementary metal oxide semiconductor (CMOS) type semiconductor device having dual gates are provided. The method includes forming an insulated first gate electrode on the P-type well, and an insulated second initial gate electrode on the N-type well. A first lower interlayer insulating layer exposing a top surface of the first gate electrode is formed on the P-type well while a second lower interlayer insulating layer exposing a top surface of the second initial gate electrode is formed on the N-type well. P-type impurity ions are selectively implanted into the second initial gate electrode to form a second gate electrode. A first ion implantation mask pattern is formed over the first gate electrode while a second ion implantation mask pattern is formed over the second gate electrode. The second lower interlayer insulating layer is etched, using the second ion implantation mask pattern as an etch mask, to expose a top surface of the N-type well.

Abstract: A manufacturing method for a transistor of an ESD protection device. First, the method forms basic elements on a semiconductor base. Next, a patterned resist layer is used as a mask to perform ion implantation in the emerged drain region so that the dopant can be implanted into the semiconductor base under the drain region to form an extended drain heavy-doped region. Then, the patterned resist layer is removed and a heat tempering processing is performed. Finally, a self-aligned salicide is formed on the surfaces of the polysilicon gate and the heavy-ion doped region. The invention utilizes an extended drain heavy-doped region as a resistance ballast between the drain contact and the polysilicon contact surface, which allows high current generated by ESD to be discharged in a more homogeneous way so as to prevent the ESD structure from being damaged.

Abstract: Dielectric layers containing an atomic layer deposited hafnium oxide and an electron beam evaporated lanthanide oxide and a method of fabricating such a dielectric layer produce a reliable dielectric layer having an equivalent oxide thickness thinner than attainable using SiO2. Forming a layer of hafnium oxide by atomic layer deposition and forming a layer of a lanthanide oxide by electron beam evaporation, where the layer of hafnium oxide is adjacent and in contact with the layer of lanthanide, provides a dielectric layer with a relatively high dielectric constant as compared with silicon oxide. The dielectric can be formed as a nanolaminate of hafnium oxide and a lanthanide oxide.

Abstract: The present invention relates to a semiconductor memory device and a method for fabricating the same. The semiconductor memory device, including: a plurality of gate structures formed on a substrate; a contact junction region formed beneath the substrate disposed in lateral sides of the respective gate structures; a trench formed by etching a portion of the substrate disposed in the contact junction region with a predetermined thickness; a dopant diffusion barrier layer formed on sidewalls of the trench; and a contact plug filled into a space created between the gate structures and inside of the trench, wherein the dopant diffusion barrier layer prevents dopants within the contact plug from diffusing out.

Abstract: Disclosed is a semiconductor device in which the capacitive element of MIMC structure has a low parasitic capacity. A process for fabrication of said semiconductor device. The semiconductor device has a capacitive element of MIMC structure, a PN photodiode, and a vertical NPN bipolar transistor which are mounted together on the same semiconductor substrate. The lower wiring layer connected to the TiN lower electrode layer of the capacitive element of MIMC structure is formed on the insulating film and the first interlayer insulating film. Between this insulating film and the p-type semiconductor substrate is the p?-type low-concentration semiconductor layer whose impurity concentration is lower than that of the p-type semiconductor substrate. This construction suppresses the parasitic capacity of the capacitive element of the MIMC structure.

Abstract: The invention includes a method of forming a capacitor structure. A first electrical node is formed, and a layer of metallic aluminum is formed over the first electrical node. Subsequently, an entirety of the metallic aluminum within the layer is transformed into one or more of AlN, AlON, and AlO, with the transformed layer being a dielectric material over the first electrical node. A second electrical node is then formed over the dielectric material. The first electrical node, second electrical node and dielectric material together define at least a portion of the capacitor structure. The invention also pertains to a capacitor structure which includes a first electrical node, a second electrical node, and a dielectric material between the first and second electrical nodes. The dielectric material consists essentially of aluminum, oxygen and nitrogen.

Abstract: A stabilized capacitor using non-oxide electrodes and high dielectric constant oxide dielectric materials and methods of making such capacitors and their incorporation into DRAM cells is provided. A preferred method includes providing a non-oxide electrode, oxidizing an upper surface of the non-oxide electrode, depositing a high dielectric constant oxide dielectric material on the oxidized surface of the non-oxide electrode, and depositing an upper layer electrode on the high dielectric constant oxide dielectric material.

Abstract: Floating gate transistors and methods of forming the same are described. In one implementation, a floating gate is formed over a substrate. The floating gate has an inner first portion and an outer second portion. Conductivity enhancing impurity is provided in the inner first portion to a greater concentration than conductivity enhancing impurity in the outer second portion. In another implementation, the floating gate is formed from a first layer of conductively doped semiconductive material and a second layer of substantially undoped semiconductive material. In another implementation, the floating gate is formed from a first material having a first average grain size and a second material having a second average grain size which is larger than the first average grain size.

Abstract: Silicon nanocrystals are applied as storage layer (6) and removed using spacer elements (11) laterally with respect to the gate electrode (5). By means of an implantation of dopant, source/drain regions (2) are fabricated in a self-aligned manner with respect to the storage layer (6). The portions of the storage layer (6) are interrupted by the gate electrode (5) and the gate dielectric (4), so that a central portion of the channel region (3) is not covered by the storage layer (6). This memory cell is suitable as a multi-bit flash memory cell in a virtual ground architecture.

Abstract: A nonvolatile semiconductor memory includes a trench isolation provided in a semiconductor substrate and an interlayer insulator provided on the semiconductor substrate. The trench isolation defines an active area extending in a first direction at the semiconductor substrate. The interlayer insulator has a wiring trench extending in a second direction intersecting the first direction. A first conductive material layer is provided at the cross-point of the active area and the wiring trench so that it is insulated from the active area. A second conductive material layer is provided in the wiring trench so that it is insulated from the first conductive material layer. A metal layer is provided in the wiring trench so that it is electrically in contact the second conductive material layer.

Abstract: A flash memory cell and a method for fabricating the same are described. The flash memory cell comprises a substrate, a select gate, a floating gate, a gate dielectric layer, a high-voltage doped region and a source region. The substrate has a first opening thereon and a second opening in the first opening. The select gate is on the sidewall of the first opening, and the floating gate is on the sidewall of the second opening. The gate dielectric layer is between the select/floating gate and the substrate. The high-voltage doped region is in the substrate under the second opening, and the source region is in the substrate beside the first opening. In the method of fabricating the flash memory cell, the select gate and the floating gate are simultaneously formed on the side walls of the first opening and the second opening, respectively.

Abstract: A flash memory device including a tunnel dielectric layer, a floating gate layer, an interlayer dielectric layer and at least two mold layers formed on a semiconductor substrate and a method of manufacturing the same are provided. By sequentially patterning the layers, a first mold layer pattern and a floating gate layer pattern aligned with each other are formed. Exposed portions of side surfaces of the first mold layer pattern are selectively lateral etched, thereby forming a first mold layer second pattern having grooves in its sidewalls. A gate dielectric layer is formed on the semiconductor substrate adjacent to the floating gate layer pattern. A control gate having a width that is determined by the grooves in the second mold layer pattern is formed on the gate dielectric layer. By removing the first mold layer second pattern, spacers are formed on sidewalls of the control gate.

Abstract: A lateral double diffused metal oxide semiconductor (LDMOS) device, and method of fabricating such a device, are provided. The method comprises the steps of: (a) providing a substrate of a first conductivity type; (b) forming within the substrate a well region of a second conductivity type, the well region having a super steep retrograde (SSR) well profile in which a doping concentration changes with depth so as to provide a lighter doping concentration in a surface region of the well region than in a region below the surface region of the well region; (c) forming a gate layer which partly overlies the well region and is insulated from the well region; and (d) forming one of a source region and a drain region in the well region. The presence of the SSR well region provides a lighter surface doping to enable a higher breakdown voltage to be obtained within the LDMOS device, and heavier sub-surface doping to decrease the on-resistance.

Abstract: According to the present invention, high-k film can be etched to provide a desired geometry without damaging the silicon underlying material. A silicon oxide film 52 is formed on a silicon substrate 50 by thermal oxidation, and a high dielectric constant insulating film 54 comprising HfSiOx is formed thereon. Thereafter, polycrystalline silicon layer 56 and high dielectric constant insulating film 54 are selectively removed in stages by a dry etching through a mask of the resist layer 58, and subsequently, the residual portion of the high dielectric constant insulating film 54 and the silicon oxide film 52 are selectively removed by wet etching through a mask of polycrystalline silicon layer 56. A liquid mixture of phosphoric acid and sulfuric acid is employed for the etchant solution. The temperature of the etchant solution is preferably equal to or lower than 200 degree C., and more preferably equal to or less than 180 degree C.

Abstract: A method and system for providing a halo implant to a semiconductor device is disclosed. The method and system includes providing a thin photoresist layer that covers a substantial amount of an active area including a source region and a drain region of the semiconductor device. The method and system further includes providing the halo implant to the semiconductor device, using the thin photoresist layer as a mask. Utilizing this thin photoresist layer, taking into account other height variables, the source and drain regions can be opened only as needed. At a 45° angle, the implant can be delivered to all transistors in the circuit in the targeted area as well as getting only a large amount of the dose (up to ¾ of the dose) to the transistor edge which sits on the trench edge.

Abstract: Example methods of manufacturing MOSFET devices are disclosed. One example method may include an oxidation, an etching, an ion implanting for a threshold voltage control to form an elevated source/drain region and thereby implements an ultra shallow junction.

Abstract: Method of producing complementary SiGe bipolar transistors. In a method of producing complementary SiGe bipolar transistors, interface oxide layers (38, 58) for NPN and PNP emitters (44, 64), are separately formed and emitter polysilicon (40, 60) is separately patterned, allowing these layers to be optimized for the respective conductivity type.

Abstract: A semiconductor structure including a semiconductor substrate, an isolation trench in the semiconductor substrate, and an alignment trench in the semiconductor substrate is disclosed. The structure also includes a dielectric layer and a metallic layer. The dielectric layer is on the semiconductor substrate and in both the isolation trench and the alignment trench. The dielectric layer fills the isolation trench and does not fill the alignment trench. The metallic layer is on the dielectric layer.

Abstract: A method of fabricating a semiconductor device having a silicon layer disposed on an insulating film. Oxygen ions are implanted into selected parts of the silicon layer, which are then oxidized to form isolation regions dividing the silicon layer into a plurality of mutually isolated active regions. As the oxidation process does not create steep vertical discontinuities, fine patterns can be formed easily on the combined surface of the active and isolation regions. The implanted oxygen ions cause oxidation to proceed quickly, finishing before a pronounced bird's beak is formed. The isolation regions themselves can therefore be narrow and finely patterned.

Abstract: A method of bonding two components by depositing an amorphous and non-hydrogenated intermediate layer (2) on one of the components (1,4) and arranging the components (1,4) in spaced relationship with the intermediate layer (2) therebetween. The method further comprises heating one or both of the components (1,4) before bringing the components (1,4) into contact. Finally, a voltage is applied to the components (1,4) to create a permanent bond between the two components.

Abstract: A first wafer is provided, and a photosensitive masking-and-bonding pattern is formed on the surface of the first wafer. Then, an etching process using the photosensitive masking-and-bonding pattern as a hard mask is performed to form a wafer pattern on the surface of the first wafer. Finally, the first wafer is bonded to a second wafer with the photosensitive masking-and-bonding pattern.

Abstract: The present invention is a method of fabricating a semiconductor device by transferring a semiconductor chip supported on a flexible support film to a mount member by means of a robot arm. This method comprises a film bending step of bending a support film so that same has a pickup face that lies along the movement direction of the robot arm and a withdrawal face that lies substantially perpendicular to this movement direction and does not interfere with the robot arm; a step of disposing the mount member, whereon the semiconductor chip is to be mounted, in a position facing the withdrawal face and flanking on the pickup face; and a step of picking up the semiconductor chip from the pickup face by means of the robot arm and transferring the semiconductor chip to the mount member.

Abstract: Semiconductor-on-insulator (SOI) structures, including large area SOI structures, are provided which have one or more regions composed of a layer (15) of a substantially single-crystal semiconductor (e.g., doped silicon) attached to a support substrate (20) composed of an oxide glass or an oxide glass-ceramic. The oxide glass or oxide glass-ceramic is preferably transparent and preferably has a strain point of less than 1000° C., a resistivity at 250° C. that is less than or equal to 1016 ?-cm, and contains positive ions (e.g., alkali or alkaline-earth ions) which can move within the glass or glass-ceramic in response to an electric field at elevated temperatures (e.g., 300–1000° C.). The bond strength between the semiconductor layer (15) and the support substrate (20) is preferably at least 8 joules/meter2. The semiconductor layer (15) can include a hybrid region (16) in which the semiconductor material has reacted with oxygen ions originating from the glass or glass-ceramic.

Abstract: An integrated circuit in which measurement of the alignment between subsequent layers has less susceptibility to stress induced shift. A first layer of the structure has a first overlay mark. A second and/or a third layer are formed in the alignment structure and on the first layer. Portions of the second and/or third layer are selectively removed from regions in and around the first overlay mark. A second overlay mark is formed and aligned to the first overlay mark. The alignment between the second overlay mark and first overlay mark may be measured with an attenuated error due to reflection and refraction or due to an edge profile shift of the first overlay mark.

Abstract: A method and system for locally processing a predetermined microstructure formed on a substrate without causing undesirable changes in electrical or physical characteristics of the substrate or other structures formed on the substrate are provided. The method includes providing information based on a model of laser pulse interactions with the predetermined microstructure, the substrate and the other structures. At least one characteristic of at least one pulse is determined based on the information. A pulsed laser beam is generated including the at least one pulse. The method further includes irradiating the at least one pulse having the at least one determined characteristic into a spot on the predetermined microstructure. The at least one determined characteristic and other characteristics of the at least one pulse are sufficient to locally process the predetermined microstructure without causing the undesirable changes.

Abstract: A method of forming an ultra-thin wafer level stack package and structure thereof are provided. The method includes providing a first wafer having a plurality of base chips thereon, selectively binding the first wafer to a second substrate, lapping the first wafer to reduce its thickness, dicing the lapped first wafer, bonding a plurality stack chips to each base chip and packaging the base chip with the bonded stack chips to form an IC package. Thus, each IC package comprises at least a base chip and a stack chip. The IC package has a size almost identical to the base chip and a thickness a little larger than the combined thickness of the base chip and the stack chip. If a known good die inspection of the base chips and stack chips are carried out prior to wafer level packaging, overall yield of the IC package is increased.

Abstract: A semiconductor element is formed by forming at least one p-n junction on a semiconductor wafer (1), a recess (8) is formed around the semiconductor element by etching, an insulating film (5) is formed on a surface of the recess, and a metal film (6a) is deposited, by sputtering or vacuum evaporation, on a surface of an exposed semiconductor layer (4) and the insulating film (5) on the semiconductor wafer. And after improving an adhesion between the semiconductor layer and the metal film by a thermal treatment, the metal film on the insulating film is removed selectively by blasting high pressured water on the surface of the semiconductor wafer. Consequently, a mesa semiconductor chip is obtained by cutting the semiconductor wafer under the recess. As a result, an electrode of the mesa semiconductor device obtained by the above method is formed uniformly on a surface of the semiconductor layer and is not formed on the insulating film.

Abstract: Nitride-based film is grown using multiple precursor fluxes. Each precursor flux is pulsed one or more times to add a desired element to the nitride-based film at a desired time. The quantity, duration, timing, and/or shape of the pulses is customized for each element to assist in generating a high quality nitride-based film.

Abstract: A doping method for forming quantum dots is disclosed, which includes following steps: providing a first precursor solution for a group II element and a second precursor solution for a group VI element; heating and mixing the first precursor solution and the second precursor solution for forming a plurality of II–VI compound cores of the quantum dots dispersing in a melting mixed solution; and injecting a third precursor solution for a group VI element and a forth precursor solution with at least one dopant to the mixed solution in turn at a fixed time interval in order to form quantum dots with multi-shell dopant; wherein the dopant described here is selected from a group consisting of transitional metal and halogen elements. This method of the invention can dope the dopants in the inner quantum dot and enhance the emission intensity efficiently.

Abstract: A method for manufacturing a semiconductor laser. As a preparative step for coating an end face of a resonator with a dielectric film, a cleavage plane of a semiconductor laminated structure that is to be the end face is subjected to a plasma cleaning to prevent a conductive film, which absorbs laser light, from attaching to the cleavage plane. During the plasma cleaning, a first process gas containing argon gas and nitrogen gas is introduced into a vacuumed ECR sputtering apparatus. After the cleavage plane is exposed to the first process gas in the plasma state for a certain time period without application of a voltage, a second process gas containing argon gas and oxygen gas is introduced, and the cleavage plane is exposed to the second process gas in the plasma state while a voltage is applied to the silicon target.

Abstract: There is provided a method for fabricating an image display device having an active matrix substrate including high-performance transistor circuits operating with high mobility as drive circuits for driving pixel portions which are arranged as a matrix. The portion of a polysilicon film formed in a drive circuit region DAR1 provided on the periphery of the pixel region PAR of the active matrix substrate SUB1 composing the image display device is irradiated and scanned with a pulse modulated laser beam or a pseudo CW laser beam to be reformed into a quasi-strip-like-crystal silicon film having a crystal boundary continuous in the scanning direction so that discrete reformed regions each composed of the quasi-strip-like-crystal silicon film are formed.

Abstract: A method is provided for forming a graded junction in a semiconductor material having a first conductivity type. Dopant having a second conductivity type opposite the first conductivity type is introduced into a selected region of the semiconductor material to define a primary dopant region therein. The perimeter of the primary dopant region defines a primary pn junction. While introducing dopant into the selected region of the semiconductor material, dopant is simultaneously introduced into the semiconductor material around the perimeter of the primary dopant region and spaced-apart from the primary pn junction. The dopant in the both the primary dopant region and in the dopant around the perimeter of the primary dopant region is then diffused to provide a graded dopant region.

Abstract: A method of plasma doping in which dilution of B2H6 is maximized for enhanced safety and stable plasma generation and sustention can be carried out without lowering of doping efficiency and in which the amount of dopant injected can be easily controlled. In particular, a method of plasma doping characterized in that B2H6 gas is used as a material containing doping impurity while He is used as a substance of high dissociation energy and that the concentration of B2H6 in mixed gas is less than 0.05%.

Abstract: A method for forming a semiconductor device is provided. In accordance with the method, a substrate (103) is provided, and a dielectric material (123) is formed on the substrate through plasma enhanced chemical vapor deposition (PECVD). The PECVD is conducted at a temperature of greater than 300° C., and utilizes an atmosphere comprising nitrogen, silane, ammonia, and helium.

Abstract: Complementary metal oxide semiconductor metal gate transistors may be formed by depositing a metal layer in trenches formerly inhabited by patterned gate structures. The patterned gate structures may have been formed of polysilicon in one embodiment. The trenches may be filled with metal by surface activating using a catalytic metal, followed by electroless deposition of a seed layer followed by superconformal filling bottom up.