Abstract: The subject of this invention is a process for detection of analytes from biological samples comprising the following process steps: a) Preparation of a reversible binding partner 1 that is immobilized on a solid phase, to which an analyte binder is reversibly bonded via a reversible binding partner 2 that is bonded to the analyte binder, whereby the analyte binder is immobilized by binding between the reversible binding partners 1 and 2, b) Addition of the biological sample and binding of the analyte to the reversible immobilized analyte binder in the case that the biological sample contains the analytes, c) Separation of the biological sample, d) Addition of a dissolving buffer, which dissolves the binding between the reversible binding partners 1 and 2, whereby the binding of the analyte to the analyte binder remains optional, and e) Detection of the analyte in the dissolving buffer in the case that the biological sample contains the analytes and determination of the absence of the analyte in the case t

Abstract: According to one embodiment, a magnetoresistive element manufacturing method is provided. In this magnetoresistive element manufacturing method, a first ferromagnetic layer, tunnel barrier layer, and second ferromagnetic layer are sequentially formed on a substrate. A conductive hard mask is formed on the second ferromagnetic layer. The hard mask is patterned. A hard layer is formed on the side surface of the hard mask. The second ferromagnetic layer, tunnel barrier layer, and first ferromagnetic layer are processed by IBE in an oblique direction by using the hard mask and hard layer as masks. The IBE etching rate of the hard layer is lower than that of the hard mask.

Abstract: An automatic analyzer detects voltage applied across electrodes, and judges whether voltage value falls within set voltage range. When the detected voltage value is lower than minimum value of set voltage range, the analyzer calculates the deficient amount of base solution based on the detected voltage value, controls a valve to supply the deficient amount of base solution, then, performs operation control of the valve so as to keep the prescribed amount of plating solution in plating solution tank, and discharges plating solution. When the detected voltage value is higher than maximum value of set voltage range, the analyzer calculates the excess amount of base solution based on the detected voltage value, controls a valve, and supplies pure water into the tank so that the base solution concentration falls within prescribed range to dilute plating solution, then controls a valve, and discharges plating solution so as to keep prescribed amount.

Abstract: Systems and methods for performing semiconductor laser annealing using dual loop control are disclosed. The first control loop operates at a first frequency and controls the output of the laser and controls the 1/f laser noise. The second control loop also controls the amount of output power in the laser and operates at second frequency lower than the first frequency. The second control loop measures the thermal emission of the wafer over an area the size of one or more die so that within-die emissivity variations are average out when determining the measured annealing temperature. The measured annealing temperature and an annealing temperature set point are used to generate the control signal for the second control loop.

Abstract: A parameter extraction method for semiconductor devices includes: providing a first multi-finger device and a second multi-finger device, wherein the gate-finger numbers between the first and second multi-finger devices are different; performing an open de-embedding, then the high-frequency test apparatus measuring a first intrinsic gate capacitance of the first multi-finger device and a second intrinsic gate capacitance of the second multi-finger device; calculating a slope according to the first and second intrinsic gate capacitances, and the first and second gate-finger numbers; performing a 3D capacitance simulation for computing the poly finger-end fringing capacitances; utilizing a long channel device for measuring the gate capacitance and extracting the intrinsic gate capacitance, then calculating an inversion channel capacitance per unit area; and computing a delta channel width of the semiconductor device, according to the slope, the poly finger-end fringing capacitance, and the inversion channel cap

Abstract: A method for testing TSV structures includes providing a wafer having a front side and a back side, the wafer further comprising a plurality of TSV structures formed therein; thinning the wafer from the back side of the wafer; forming a first under bump metallization layer on the back side of the wafer blanketly; providing a probing card to the front side of the wafer to test the TSV structures; and patterning the first UBM layer.

Abstract: Disclosed herein is a semiconductor device, including: a semiconductor substrate; an integrated circuit formed on a first main surface of the semiconductor substrate; a penetrating electrode that penetrates the semiconductor substrate in the thickness direction and has its one end electrically connected to the integrated circuit; a bump electrode formed on a second main surface of the semiconductor substrate and electrically connected to another end of the penetrating electrode; and a test pad electrode formed on the second main surface of the semiconductor substrate and electrically connected to the bump electrode.

Abstract: In producing a semiconductor light-emitting chip whose substrate is composed of a sapphire single crystal, cracking in semiconductor light-emitting elements in the obtained semiconductor light-emitting chip is suppressed.

Abstract: In a method for manufacturing an organic EL device, a first luminescent layer emitting first color light is formed over a first anode disposed on a substrate by coating. A second luminescent layer emitting second color light is formed over a second anode disposed on the substrate. An intermediate layer having electron injection performance is formed on the first luminescent layer and the second luminescent layer. A third luminescent layer emitting third color light is formed over the intermediate layer and a third anode disposed on the substrate by vapor deposition. A cathode is formed on the third luminescent layer.

Abstract: A substrate and a delamination film are separated by a physical means, or a mechanical means in a state where a metal film formed over a substrate, and a delamination layer comprising an oxide film including the metal and a film comprising silicon, which is formed over the metal film, are provided. Specifically, a TFT obtained by forming an oxide layer including the metal over a metal film; crystallizing the oxide layer by heat treatment; and performing delamination in a layer of the oxide layer or at both of the interface of the oxide layer is formed.

Abstract: A method and apparatus for forming a crystalline semiconductor layer on a substrate are provided. A semiconductor layer is formed by vapor deposition. A pulsed laser melt/recrystallization process is performed to convert the semiconductor layer to a crystalline layer. Laser, or other electromagnetic radiation, pulses are formed into a pulse train and uniformly distributed over a treatment zone, and successive neighboring treatment zones are exposed to the pulse train to progressively convert the deposited material to crystalline material.

Abstract: A light emitting diode comprising an epitaxial layer structure, a first electrode, and a second electrode. The first and second electrodes are separately disposed on the epitaxial layer structure, and the epitaxial layer structure has a root-means-square (RMS) roughness less than about 3 at a surface whereon the first electrode is formed.

Abstract: A microelectromechanical (MEMS) device is fabricated from a wafer having a plurality of die regions with grooves and MEMS components formed on a wafer surface at each die region. A first metal having a relatively high melting temperature is formed on sidewalls of each groove, and a cap is attached at each die region to provide a closed cavity which encloses the grooves and MEMS components. Bottoms of the grooves are opened by thinning the wafer thereby establishing through-hole vias extending through the wafer at each die region, for accessing the cavity for inserting or removing material. The vias are sealed by interacting a second metal having a relatively low melting temperature with the first metal layer to form intermetallic compounds with higher melting temperature that maintain the seal during subsequent lower temperature operations.

Abstract: Semiconductor devices having integrated nanochannels confined by nanometer spaced electrodes, and VLSI (very large scale integration) planar fabrication methods for making the devices. A semiconductor device includes a bulk substrate and a first metal layer formed on the bulk substrate, wherein the first metal layer comprises a first electrode. A nanochannel is formed over the first metal layer, and extends in a longitudinal direction in parallel with a plane of the bulk substrate. A second metal layer is formed over the nanochannel, wherein the second metal layer comprises a second electrode. A top wall of the nanochannel is defined at least in part by a surface of the second electrode and a bottom wall of the nanochannel is defined by a surface of the first electrode.

Abstract: Gas sensor materials and methods are disclosed for preparing and using the same to produce gas sensor structures. Also disclosed are gas sensor structures and systems that employ these disclosed materials. A gas sense-enhancing metal such as platinum may be added to a gas sensitive metal oxide material in a manner that more highly disperses the added platinum than conventional methods so as to more effectively utilize the platinum at a lower concentration, thus achieving a more cost effective solution. An ink vehicle may also be used for deposition of a gas sensitive material (e.g. on the surface of integrated circuit) that is formulated to allow “burn-out” of ink vehicle components at relatively low temperatures as compared to conventional ink vehicles.

Abstract: A method of manufacturing a semiconductor device including at least one of the following steps: (1) Forming a plurality of lower electrodes over a substrate. (2) Forming a first stop film over the lower electrodes. (3) Forming a filling layer over the first stop film. (4) Forming a second stop film over the filling layer. (5) Forming a first interlayer insulating layer over the second stop film. (6) Forming a plurality of upper electrodes over the first interlayer insulating layer. (7) Forming a second interlayer insulating layer over the upper electrodes. (8) Etching the second interlayer insulating layer and the first interlayer insulating layer to form a cavity. (9) Forming a contact ball in the cavity.

Abstract: In a method for manufacturing a micromechanical membrane structure, a doped area is created in the front side of a silicon substrate, the depth of which doped area corresponds to the intended membrane thickness, and the lateral extent of which doped area covers at least the intended membrane surface area. In addition, in a DRIE (deep reactive ion etching) process applied to the back side of the silicon substrate, a cavity is created beneath the doped area, which DRIE process is aborted before the cavity reaches the doped area. The cavity is then deepened in a KOH etching process in which the doped substrate area functions as an etch stop, so that the doped substrate area remains as a basic membrane over the cavity.

Abstract: Provided is a method of enhancing thermoelectric performance by surrounding crystalline semiconductors with nanoparticles by contacting a bismuth telluride material with a silver salt under a substantially inert atmosphere and a temperature approximately near the silver salt decomposition temperature; and recovering a metallic bismuth decorated material comprising silver telluride crystal grains.

Abstract: A crystalline-based silicon photoelectric conversion device comprises: an intrinsic silicon-based layer and a silicon-based layer of a first conductivity type, on one surface of a single-crystal silicon substrate of the first conductivity type; and an intrinsic silicon-based and a silicon-based layer of an opposite conductivity type, in this order on the other surface of the silicon substrate. At least one of forming the intrinsic silicon-based layer of the first conductivity type layer-side forming the intrinsic silicon-based layer of the opposite conductivity type layer-side includes: forming a first intrinsic silicon-based thin-film layer having a thickness of 1-10 nm on the silicon substrate; plasma-treating the silicon substrate in a gas containing mainly hydrogen; and forming a second intrinsic silicon-based thin-film layer on the first intrinsic silicon-based thin-film.

Abstract: An image detector comprises a plurality of photosensitive detector unit cells interconnected to a plurality of integrated circuits by a plurality of direct bond interconnects. Each unit cell includes an absorber layer and a separation layer. The absorber layer absorbs incident photons such that the absorbed photons excite photocurrent comprising first charged carriers and second charged carriers having opposite polarities. The separation layer separates the first charged carriers for collection at one or more first contacts and the second charged carriers for collection at one or more second contacts. The first and second contacts include the direct bond interconnects to conduct the first charged carriers and the second charged carriers from the unit cells in order to facilitate image processing.

Abstract: An image sensor and a method of manufacturing the same. The image sensor includes a plurality of photoelectric conversion units that are horizontally arranged and selectively emit electric signals by absorbing color beams.

Abstract: A method for manufacturing a thin film solar cell includes depositing a front electrode on a substrate in a chamber, etching the front electrode formed on the substrate to form an uneven portion on the surface of the front electrode, forming a photoelectric conversion unit on the front electrode, and forming a back electrode on the photoelectric conversion unit. The depositing of the front electrode includes depositing the front electrode while reducing a process pressure of the chamber from a first pressure to a second pressure lower than the first pressure. The etching of the front electrode form the uneven portion of the front electrode so that a top portion of the uneven portion includes a portion formed at the second pressure.

Abstract: A method of manufacturing an image sensor having a backside illumination (BSI) structure includes forming a wiring unit on a front side of a semiconductor substrate, forming an anti-reflective layer in an active pixel sensor (APS) region on a back side of the semiconductor substrate, a photodiode being between the back and front sides of the semiconductor substrate, forming an etch stopping layer on the anti-reflective layer, forming an interlayer insulating layer on the etch stopping layer, the interlayer insulating layer having an etch selectivity with respect to the etch stopping layer, and etching the interlayer insulating layer in the APS region using the etch stopping layer as an etch stopping point.

Abstract: A method for forming a thin film photovoltaic device. The method includes providing a transparent substrate including a surface region. A first electrode layer is formed overlying the surface region. A copper layer is formed overlying the first electrode layer and an indium layer overlying the copper layer to form a multi-layered structure. The method subjects at least the multi-layered structure to a thermal treatment process in an environment containing a sulfur bearing species and form a copper indium disulfide material. The copper indium disulfide material includes a thickness of substantially copper sulfide material. The thickness of the copper sulfide material is removed to expose a surface region having a copper poor surface characterized by a copper to indium atomic ratio of less than about 0.95:1. The method subjects the copper poor surface to a metal cation species to convert the copper poor surface from an n-type semiconductor characteristic to a p-type semiconductor characteristic.

Abstract: This invention aims to provide a laminated structure and an integrated structure of a high production efficiency for a CIS based thin-film solar cell, which can produce a high-resistance buffer layer of the CIS based thin-film solar cell efficiently on a series of production lines and which needs no treatment of wastes or the like, and a manufacturing method for the structures. The CIS based thin-film solar cell includes a back electrode, a p-type CIS based light absorbing layer, a high-resistance buffer layer and an n-type transparent conductive film laminated in this order. The high-resistance buffer layer and the n-type transparent conductive film are formed of thin films of a zinc oxide group. The buffer layer contacts the p-type CIS based light absorbing layer directly, and has a resistivity of 500?·cm or higher.

Abstract: Disclosed is a method for manufacturing a front electrode for solar cells including: filling a paste for forming electrodes in a mold in which a depression pattern corresponding to a pattern of a front electrode is imprinted, drying the paste and bringing an adhesive film in contact with the paste to transfer the paste from the mold, adding the adhesive film to the semiconductor substrate such that the paste is directed toward a semiconductor substrate, and baking the paste transferred from the adhesive film to form a front electrode on the semiconductor substrate.

Abstract: A method is provided for preparing a printed metal surface for the deposition of an organic semiconductor material. The method provides a substrate with a top surface, and a metal layer is formed overlying the substrate top surface. Simultaneous with a thermal treatment of the metal layer, the metal layer is exposed to a gaseous atmosphere with thiol molecules. In response to exposing the metal layer to the gaseous atmosphere with thiol molecules, the work function of the metal layer is increased. Subsequent to the thermal treatment, an organic semiconductor material is deposited overlying the metal layer. In one aspect, the metal layer is exposed to the gaseous atmosphere with thiol molecules by evaporating a liquid containing thiol molecules in an ambient air atmosphere. Alternatively, a delivery gas is passed through a liquid containing thiol molecules. An organic thin-film transistor (OTFT) and OTFT fabrication process are also provided.

Abstract: A method of forming a memory cell includes forming programmable material within an opening in dielectric material over an elevationally inner conductive electrode of the memory cell. Conductive electrode material is formed over the dielectric material and within the opening. The programmable material within the opening has an elevationally outer edge surface angling elevationally and laterally inward relative to a sidewall of the opening. The conductive electrode material is formed to cover over the angling surface of the programmable material within the opening. The conductive electrode material is removed back at least to an elevationally outermost surface of the dielectric material and to leave the conductive electrode material covering over the angling surface of the programmable material within the opening. The conductive electrode material constitutes at least part of an elevationally outer conductive electrode of the memory cell. Memory cells independent of method of manufacture are also disclosed.

Abstract: An object is to provide a semiconductor device of which a manufacturing process is not complicated and by which cost can be suppressed, by forming a thin film transistor using an oxide semiconductor film typified by zinc oxide, and a manufacturing method thereof. For the semiconductor device, a gate electrode is formed over a substrate; a gate insulating film is formed covering the gate electrode; an oxide semiconductor film is formed over the gate insulating film; and a first conductive film and a second conductive film are formed over the oxide semiconductor film. The oxide semiconductor film has at least a crystallized region in a channel region.

Abstract: A die fixing method is disclosed which includes providing a substrate having a metallized surface, forming a joining material on the metallized surface and placing a die alignment member with a plurality of openings on the substrate so that portions of the joining material are exposed through the openings. The method further includes placing a plurality of dies in the openings of the die alignment member with a bottom side of each die in contact with part of the joining material and attaching the plurality of dies to the metallized surface of the substrate at an elevated temperature and pressure, the die alignment member withstanding the elevated temperature and pressure. The die alignment member is removed from the substrate after the plurality of dies are attached to the metallized surface of the substrate.

Abstract: The present invention relates to a method for making a chip package. The method includes the following steps: (a) providing a substrate having at least one conductive via; (b) disposing the substrate on a carrier; (c) removing part of the substrate, so as to expose the conductive via, and form at least one through via; (d) disposing a plurality of chips on a surface of the substrate, wherein the chips are electrically connected to the through via of the substrate; (e) forming an encapsulation; (f) removing the carrier; (g) conducting a flip-chip mounting process; (h) removing the encapsulation; and (i) forming a protective material. Whereby, the carrier and the encapsulation can avoid warpage of the substrate during the manufacturing process.

Abstract: A method of manufacturing is provided that includes placing a removable cover on a surface of a substrate. The substrate includes a first semiconductor chip positioned on the surface. The first semiconductor chip includes a first sidewall. The removable cover includes a second sidewall positioned opposite the first sidewall. A first underfill is placed between the first semiconductor chip and the surface wherein the second sidewall provides a barrier to flow of the first underfill. Various apparatus are also disclosed.

Abstract: Disclosed are a GaN-based compound power semiconductor device and a manufacturing method thereof, in which on a GaN power semiconductor element, a contact pad is formed for flip-chip bonding, and a bonding pad of a module substrate to be mounted with the GaN power semiconductor element is formed with a bump so as to modularize an individual semiconductor element. In the disclosed GaN-based compound power semiconductor device, an AlGaN HEMT element is flip-chip bonded to the substrate, so that heat generated from the element can be efficiently radiated.

Abstract: According to one embodiment, a method of manufacturing a semiconductor device, a bonding layer is formed on a first surface of a chip region of a semiconductor wafer. Semiconductor chips are singulated along a dicing region. The semiconductor chips are stacked stepwise via the bonding layer. In formation of the bonding layer of the semiconductor chip, in at least a part of a first region of the first surface not in contact with the other semiconductor chip in a stacked state, a projected section where the bonding layer is formed thicker than the bonding layer in a second region that is in contact with the other semiconductor chip is provided.

Abstract: An embodiment is a method for semiconductor packaging. The method comprises attaching a chip to a carrier substrate through a first side of a jig, the chip being attached by bumps; applying balls to bond pads on the carrier substrate through a second side of the jig; and simultaneously reflowing the bumps and the balls. According to a further embodiment, a packaging jig comprises a cover, a base, and a connector. The cover has a first window through the cover. The base has a second window through the base. The first window exposes a first surface of a volume intermediate the cover and the base, and the second window exposes a second surface of the volume. The first surface is opposite the volume from the second surface. The connector aligns and couples the cover to the base.

Abstract: A method of manufacturing a semiconductor package structure is provided. A heat-conductive block is adhered to a portion of a second surface of a conductive substrate via a first adhesive layer. An opening is formed by performing a half-etching process on a first surface of the conductive substrate. The remaining conductive substrate is patterned to form leads and expose a portion of the heat-conductive block. Each lead has a first portion and a second portion. A thickness of the first portion is greater than a thickness of the second portion. A first lower surface of the first portion and a second lower surface of the second portion are coplanar. A chip is disposed on the exposed portion of the heat-conductive block and electrically connected to the second portions of the leads. A first bottom surface of the heat-conductive block and a second bottom surface of a molding compound are coplanar.

Abstract: A device including two mounting surfaces. One embodiment provides a power semiconductor chip and having a first electrode on a first surface and a second electrode on a second surface opposite to the first surface. A first external contact element and a second external contact element, are both electrically coupled to the first electrode of the semiconductor chip. A third external contact element and a fourth external contact element, both electrically coupled to the second electrode of the semiconductor chip. A first mounting surface is provided on which the first and third external contact elements are disposed. A second mounting surface is provided on which the second and fourth external contact elements are disposed.

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 provided that includes a substrate, a static random access memory (SRAM) unit cell formed in the substrate, a first metal layer formed over the substrate the first metal layer providing local interconnection to the SRAM unit cell, a second metal layer formed over the first metal layer, the second metal layer including: a bit line and a complementary bit line each having a first thickness and a Vcc line disposed between the bit line and the complementary bit line, and a third metal layer formed over the second metal layer, the third metal layer including a word line having a second thickness greater than the first thickness.

Abstract: A thyristor device includes a semiconductor body and a conductive anode. The semiconductor body has a plurality of doped layers forming a plurality of dopant junctions and includes an optical thyristor, a first amplifying thyristor, and a switching thyristor. The conductive anode is disposed on a first side of the semiconductor body. The optical thyristor is configured to receive incident radiation to generate a first electric current, and the first amplifying thyristor is configured to increase the first electric current from the optical thyristor to at least a threshold current. The switching thyristor switches to the conducting state in order to conduct a second electric current from the anode and through the semiconductor body.

Abstract: A semiconductor device includes a first semiconductor region of a first conductivity type; a second semiconductor region of a second conductivity type, disposed on a surface of the first semiconductor region, and having an impurity concentration higher than that of the first semiconductor region; a trench that penetrates the second semiconductor region to reach the first semiconductor region; a first electrode disposed inside the trench via an insulating film; a first recess portion disposed deeper than an upper end of the first electrode, in a surface layer of the second semiconductor region, so as to be in contact with the trench; and a second electrode embedded in the first recess portion.

Abstract: A method for removing germanium suboxide between a germanium (Ge) substrate and a dielectric layer made of metal oxide includes causing a supercritical fluid composition that includes a supercritical carbon dioxide fluid and an oxidant to diffuse into the germanium suboxide such that metal residues in the dielectric layer, the germanium suboxide and the oxidant are subjected to a redox reaction so as to reduce the germanium suboxide into germanium.

Abstract: Disclosed herein is a solid-state image pickup device including: a photoelectric conversion section configured to convert incident light into a signal charge; a transfer transistor configured to read the signal charge from the photoelectric conversion section and transfer the signal charge; and an amplifying transistor configured to amplify the signal charge read by the transfer transistor, wherein a compressive stress film having a compressive stress is formed on the amplifying transistor.

Abstract: A method of forming a semiconductor device is presented. The method includes providing a substrate. The method further includes forming a gate stack having a gate electrode on the substrate, which includes forming a metal gate electrode layer. A buffer gate electrode layer is formed on top of the metal gate electrode layer and a top gate electrode layer having a poly-silicon alloy is formed over the metal gate electrode layer.

Abstract: Embodiments of the disclosed technology disclose manufacture methods of a thin film transistor and an array substrate and a mask therefor are provided. The manufacture method of the thin film transistor comprises: patterning a wire layer by using a exposure machine and a mask with a first exposure amount larger than a normal exposure amount during formation of source and drain electrodes; forming a semiconductor layer on the patterned wire layer; patterning the semiconductor layer by using the exposure machine and the mask with a second exposure amount smaller than the first exposure amount. The mask comprises a source region for forming the source electrode, a drain region for forming the drain electrode and a slit provided between the source region and the drain region, and the width of the slit is smaller than the resolution of the exposure machine.

Abstract: One illustrative method disclosed herein includes forming a plurality of trenches in a semiconductor substrate to thereby define an initial fin structure, forming sidewall spacers adjacent the initial fin structure, wherein the spacers cover a first portion of the initial fin structure and expose a second a portion of the initial fin structure, performing a doping process to form N-type doped regions in at least the exposed portion of the initial fin structure, and performing an etching process to remove at least a portion of the doped regions and thereby define a final fin structure that is vertically spaced apart from the substrate.

Abstract: A method of manufacturing a semiconductor device is provided, in which after forming a gate stack and a first spacer thereof, a second spacer and a third spacer are formed; and then an opening is formed between the first spacer and the third spacer by removing the second spacer. The range of the formation for the raised active area 220 is limited by forming an opening 214 between the first spacer 208 and the third spacer 212. The raised active area 220 is formed in the opening 214 in a self-aligned manner, so that a better profile of the raised active area 220 may be achieved and the possible shorts between adjacent devices caused by an unlimited manner may be avoided. Moreover, based on such a manufacturing method, it is easy to make the gate electrode 204 to be flushed with the raised active area 220, and is also easy to implement the dual stress nitride process so as to increase the mobility of the device.

Abstract: A method of fabricating a semiconductor device includes forming gate structures on PMOS and NMOS transistor regions of the semiconductor substrate, forming epitaxial blocking layers on source/drain regions of PMOS and NMOS transistor regions using a nitridation process, then selectively removing one of the epitaxial blocking layers, and using a SEG process to form an epitaxial layer on respective source/drain regions while shielding the other source/drain regions with a remaining epitaxial blocking layer.

Abstract: Methods of forming semiconductor devices are provided. The methods may include forming a gate pattern on an active region of a substrate. The methods may further include performing a deoxidization treatment on the substrate.

Abstract: A method of forming stressed-channel NMOS transistors and strained-channel PMOS transistors forms p-type source and drain regions before an n-type source and drain dopant is implanted and a stress memorization layer is formed, thereby reducing the stress imparted to the n-channel of the PMOS transistors. In addition, a non-conductive layer is formed after the p-type source and drain regions are formed, but before the n-type dopant is implanted. The non-conductive layer allows shallower n-type implants to be realized, and also serves as a buffer layer for the stress memorization layer.