Abstract: Embodiments herein describe techniques for a semiconductor device including a first transistor stacked above and self-aligned with a second transistor, where a shadow of the first transistor substantially overlaps with the second transistor. The first transistor includes a first gate electrode, a first channel layer including a first channel material and separated from the first gate electrode by a first gate dielectric layer, and a first source electrode coupled to the first channel layer. The second transistor includes a second gate electrode, a second channel layer including a second channel material and separated from the second gate electrode by a second gate dielectric layer, and a second source electrode coupled to the second channel layer. The second source electrode is self-aligned with the first source electrode, and separated from the first source electrode by an isolation layer. Other embodiments may be described and/or claimed.

Abstract: In a gate last metal gate process for forming a transistor, a dielectric layer is formed over an intermediate transistor structure, the intermediate structure including a dummy gate electrode, typically formed of polysilicon. Various processes, such as patterning the polysilicon, planarizing top layers of the structure, and the like can remove top portions of the dielectric layer, which can result in decreased control of gate height when a metal gate is formed in place of the dummy gate electrode, decreased control of fin height for finFETs, and the like. Increasing the resistance of the dielectric layer to attack from these processes, such as by implanting silicon or the like into the dielectric layer before such other processes are performed, results in less removal of the top surface, and hence improved control of the resulting structure dimensions and performance.

Abstract: A method of forming a gate includes: forming a dummy gate; forming an inter layer dielectric (ILD) laterally adjacent to the dummy gate; doping a dopant into the dummy gate and the ILD, in which a surface dopant concentration of the dummy gate is lower than a surface dopant concentration of the ILD; removing the dummy gate to form a cavity after doping the dopant into the dummy gate and the ILD; and forming the gate in the cavity.

Abstract: Shallow trench isolation structures are provided for use with UTBB (ultra-thin body and buried oxide) semiconductor substrates, which prevent defect mechanisms from occurring, such as the formation of electrical shorts between exposed portions of silicon layers on the sidewalls of shallow trench of a UTBB substrate, in instances when trench fill material of the shallow trench is subsequently etched away and recessed below an upper surface of the UTBB substrate.

Abstract: A method of making a semiconductor device, the method includes forming an active region in a substrate. The method further includes forming a first gate structure over the active region, where the forming the first gate structure includes forming a first interfacial layer. An entirety of a top surface of the first interfacial layer is a curved convex surface. Furthermore, the method includes forming a first high-k dielectric over the first interfacial layer. Additionally, the method includes forming a first gate electrode over a first portion of the first high-k dielectric and surrounded by a second portion of the first high-k dielectric.

Abstract: An insulating film provided between adjacent pixels is referred to as a bank, a partition, a barrier, an embankment or the like, and is provided above a source wiring or a drain wiring for a thin film transistor, or a power supply line. In particular, at an intersection portion of these wirings provided in different layers, a larger step is formed there than in other portions. Even in a case that the insulating film provided between adjacent pixels is formed by a coating method, there is a problem that thin portions are partially formed due to this step and the withstand pressure is reduced. In the present invention, a dummy material is arranged near the large step portion, particularly, around the intersection portion of wirings, so as to alleviate unevenness formed thereover. The upper wring and the lower wiring are arranged in a misaligned manner so as not to align the end portions.

Abstract: A semiconductor device comprises a substrate and first and second stress-generating epitaxial regions on the substrate and spaced apart from each other. A channel region is on the substrate and positioned between the first and second stress-generating epitaxial regions. A gate electrode is on the channel region. The channel region is an epitaxial layer, and the first and second stress-generating epitaxial regions impart a stress on the channel region.

Abstract: A method for fabricating a semiconductor device comprises providing a substrate having a core oxide layer and an I/O oxide layer formed thereon. The I/O oxide layer has an I/O mask layer formed thereon. The method also includes forming an I/O dummy gate on the I/O mask layer and a core dummy gate on the core oxide layer, forming an etch barrier layer on the substrate covering the dummy gates, forming a dielectric layer on the etch barrier layer, and planarizing the etch barrier layer and the dielectric layer to expose the top surface of the dummy gates. The method further includes simultaneously removing the I/O and core dummy gates to form I/O and core gate grooves, removing the core oxide layer, removing the I/O mask layer, depositing a dielectric layer in the core gate groove, and forming a metal gate layer filling the I/O and core gate grooves.

Abstract: Disclosed is a semiconductor device and a method for fabricating the semiconductor device. The method for fabricating the semiconductor device comprises steps of: forming a side cliff in a substrate in accordance with a gate mask pattern, the side cliff being substantially vertical to a substrate surface; forming a dielectric layer on the substrate that comprises the side cliff; etching the dielectric layer to have the dielectric layer left only on the side cliff, as a dielectric wall; and burying the side cliff by a substrate growth, the burying is performed up to a level higher than the upper end of the dielectric wall.

Abstract: A semiconductor device includes a doped layer which contains a first dopant of a first conductivity type. In the doped layer, a counter-doped zone is formed in an edge area that surrounds an element area of the semiconductor device. The counter-doped zone contains at least the first dopant and a second dopant of a second conductivity type, which is the opposite of the first conductivity type. A concentration of the second dopant is at least 20% and at most 100% of a concentration of the first dopant. The dopants in the counter-doped zone decrease charge carrier mobility and minority carrier lifetime such that the dynamic robustness of the semiconductor device is increased.

Abstract: In a method for fabricating a semiconductor device, a substrate may be provided that includes: a base, an active fin that projects from an upper surface of the base and is integrally formed with the base, and a buffer oxide film pattern formed on the active fin in contact with the active fin. A first dummy gate film may be formed on the substrate to cover the buffer oxide film pattern and the first dummy gate film may be smoothed to expose the buffer oxide film pattern. A second dummy gate film may be formed on the exposed buffer oxide film pattern and the first dummy gate film.

Abstract: A method for fabricating an integrated device is disclosed. In an embodiment, a hard mask layer with a limited thickness is formed over a gate electrode layer. A treatment is provided to the hard mask layer to make the hard mask layer more resistant to a wet etch solution. Then, a patterning is provided on the treated hard mask layer and the gate electrode to from a gate structure.

Abstract: A method of forming a semiconductor device structure includes forming an interlevel dielectric (ILD) layer over a semiconductor substrate and a dummy transistor gate structure formed on the substrate; infusing a shallow gas cluster ion beam (GCIB) layer in a top portion of the ILD layer; and removing at least one layer from the dummy transistor gate structure, wherein the at least one layer comprises a same material as the ILD layer and wherein the GCIB layer has a slower etch rate with respect to the ILD layer.

Abstract: A technology is capable of simplifying a process of manufacturing an asymmetric device in forming a Tunneling Field Effect Transistor (TFET) structure. A method for manufacturing a semiconductor device comprises forming a conductive pattern over a semiconductor substrate, implanting impurity ions with the conductive pattern as a mask to form a first junction region in the semiconductor substrate, forming a first insulating film planarized with the conductive pattern over the first junction region, etching the top of the conductive pattern to expose a sidewall of the first insulating film, forming a spacer at the sidewall of the first insulating film disposed over the conductive pattern, etching the conductive pattern with the spacer as an etching mask to form a gate pattern, and forming a second junction region in the semiconductor substrate with the gate pattern as a mask.

Abstract: An electronic device can include a drain region of a transistor, a channel region of the transistor, and a doped region that is disposed under substantially all of the channel region, is not disposed under substantially all of a heavily doped portion of the drain region, and has a higher dopant concentration compared to the channel region. A process of forming an electronic device can include forming a drain region, a channel region, and a doped region, wherein the drain region has a conductivity type opposite that of the channel and doped region. After forming the drain, channel, and doped regions, the doped region is disposed under substantially all of the channel region, the doped region is not disposed under substantially all of a heavily doped portion of the drain region, and the drain region is laterally closer to the doped region than to the channel region.

Abstract: A method of fabricating a semiconductor device includes forming an interlayer dielectric on a substrate, the interlayer dielectric including first and second openings respectively disposed in first and second regions formed separately in the substrate; forming a first conductive layer filling the first and second openings; etching the first conductive layer such that a bottom surface of the first opening is exposed and a portion of the first conductive layer in the second opening remains; and forming a second conductive layer filling the first opening and a portion of the second opening.

Abstract: An electronic device can include a gate electrode having different portions with different conductivity types. In an embodiment, a process of forming the electronic device can include forming a semiconductor layer over a substrate, wherein the semiconductor layer has a particular conductivity type. The process can also include selectively doping a region of the semiconductor layer to form a first doped region having an opposite conductivity type. The process can further include patterning the semiconductor layer to form a gate electrode that includes a first portion and a second portion, wherein the first portion includes a portion of the first doped region, and the second region includes a portion of the semiconductor layer outside of the first doped region. In a particular embodiment, the electronic device can have a gate electrode having edge portions of one conductivity type and a central portion having an opposite conductivity type.

Abstract: A region is locally modified so as to create a zone that extends as far as at least part of the surface of the region and is formed from a material that can be removed selectively with respect to the material of the region. The region is then covered with an insulating material. An orifice is formed in the insulating material emerging at the surface of the zone. The selectively removable material is removed from the zone through the orifice so as to form a cavity in place of the zone. The cavity and the orifice are then filled with at least one electrically conducting material so as to form a contact pad.

Abstract: A method of forming a device is presented. The method includes providing a substrate prepared with an active device region. The active device region includes gate stack layers of a gate stack including at least a gate electrode layer over a gate dielectric layer. A first mask is provided on the substrate corresponding to the gate. The substrate is patterned to at least remove portions of a top gate stack layer unprotected by the first mask. A second mask is also provided on the substrate with an opening exposing a portion of the first mask and the top gate stack layer. A channel well is formed by implanting ions through the opening and gate stack layers into the substrate.

Abstract: There is provided a technique for improving the flatness at the surface of members embedded in a plurality of recesses without resulting in an increase in the time required for the manufacturing processes. According to this technique, the dummy patterns can be placed up to the area near the boundary BL between the element forming region DA and dummy region FA by placing the first dummy pattern DP1 of relatively wider area and the second dummy pattern DP2 of relatively small area in the dummy region FA. Thereby, the flatness of the surface of the silicon oxide film embedded within the isolation groove can be improved over the entire part of the dummy region FA. Moreover, an increase of the mask data can be controlled when the first dummy patterns DP1 occupy a relatively wide region among the dummy region FA.

Abstract: A method of fabricating a semiconductor device includes forming a first trench and a second trench on a semiconductor substrate and forming a first metal layer in the first and second trenches. The first metal layer is then removed, at least partially, from within the first trench but not the second trench. A second metal layer and a third metal layer are formed in the first and second trenches. A thermal process is used to reflow the second metal layer and the third metal layer.

Abstract: A method of manufacturing a semiconductor device includes forming a polysilicon pattern, source/drain, and side-wall spacer, epitaxially growing silicide films on the source/drain, epitaxially growing silicon films selectively on the silicide film, removing the polysilicon pattern, forming a gate insulating film and gate electrode.

Abstract: The present disclosure provides a method of fabricating a semiconductor device that includes providing a semiconductor substrate, forming first and second transistors in the substrate, the first transistor having a first gate structure that includes a first dummy gate, the second transistor having a second gate structure that includes a second dummy gate, removing the first and second dummy gates thereby forming a first trench and a second trench, respectively, forming a first metal layer to partially fill in the first and second trenches, removing the first metal layer within the first trench, forming a second metal layer to partially fill in the first and second trenches, forming a third metal layer to partially fill in the first and second trenches, reflowing the second metal layer and the third metal layer, and forming a fourth metal layer to fill in the remainder of the first and second trenches.

Abstract: A method is provided for fabricating a semiconductor device that includes providing a semiconductor substrate having a first region and a second region, forming a high-k dielectric layer over the substrate, forming a silicon layer over the high-k dielectric layer, forming a hard mask layer over the silicon layer, patterning the hard mask layer, silicon layer, and high-k dielectric layer to form first and second gate structures over the first and second regions, respectively, forming a contact etch stop layer (CESL) over the first and second gate structures, modifying a profile of the CESL by an etching process, forming an inter-layer dielectric (ILD) over the modified CESL, performing a chemical mechanical polishing (CMP) on the ILD to expose the silicon layer of the first and second gate structures, respectively, and removing the silicon layer from the first and second gate structures, respectively, and replacing it with metal gate structures.

Abstract: A method of manufacturing a memory device includes an nMOS region and a pMOS region in a substrate. A first gate is defined within the nMOS region, and a second gate is defined in the pMOS region. Disposable spacers are simultaneously defined about the first and second gates. The nMOS and pMOS regions are selectively masked, one at a time, and LDD and Halo implants performed using the same masks as the source/drain implants for each region, by etching back spacers between source/drain implant and LDD/Halo implants. All transistor doping steps, including enhancement, gate and well doping, can be performed using a single mask for each of the nMOS and pMOS regions. Channel length can also be tailored by trimming spacers in one of the regions prior to source/drain doping.

Abstract: A method of fabricating a MOS transistor having a thinned channel region is described. The channel region is etched following removal of a dummy gate. The source and drain regions have relatively low resistance with the process.

Abstract: A lateral MOS device is formed in a body having a surface and is formed by a semiconductor layer of a first conductivity type; a drain region of a second conductivity type, formed in the semiconductor layer and facing the surface; a source region of the second conductivity type, formed in the semiconductor layer and facing the surface; a channel of the first conductivity type, formed in the semiconductor layer between the drain region and the source region and facing the surface; and an insulated gate region, formed on top of the surface over the channel region. In order to improve the dynamic performance, a conductive region extends only on one side of the insulated gate region, on top of the drain region but not on top of the insulated gate region.

Abstract: A region is locally modified so as to create a zone that extends as far as at least part of the surface of the region and is formed from a material that can be removed selectively with respect to the material of the region. The region is then covered with an insulating material. An orifice is formed in the insulating material emerging at the surface of the zone. The selectively removable material is removed from the zone through the orifice so as to form a cavity in place of the zone. The cavity and the orifice are then filled with at least one electrically conducting material so as to form a contact pad.

Abstract: A semiconductor structure comprises a silicon substrate of a first conductivity type including wells of a second conductivity type formed on a surface thereof. The wells may be laterally isolated by shallow trench isolation. Transistors are formed in the wells by first forming several chemically distinct layers. Anisotropic etching then forms openings in a top one of the layers. A blanket dielectric layer is formed in the openings and on the layers. Anisotropic etching removes portions of the blanket dielectric layer from planar surfaces of the substrate but not from sidewalls of the openings to form dielectric spacers separated by gaps within the openings. Gate oxides are formed by oxidation of exposed areas of the substrate. Ion implantation forms channels beneath the gate oxides. Polysilicon deposition followed by chemical-mechanical polishing defines gates in the gaps. The chemically distinct layers are then stripped without removing the dielectric spacers.

Abstract: A method forms a gate conductor over a substrate, and simultaneously forms spacers on sides of the gate conductor and a gate cap on the top of the gate conductor. Isolation regions are formed in the substrate and the method implants an impurity into exposed regions of the substrate not protected by the gate conductor and the spacers to form source and drain regions. The method deposits a mask over the gate conductor, the spacers, and the source and drain regions. The mask is recessed to a level below a top of the gate conductor but above the source and drain regions, such that the spacers are exposed and the source and drain regions are protected by the mask. With the mask in place, the method then safely removes the spacers and the gate cap, without damaging the source/drain regions or the isolation regions (which are protected by the mask). Next, the method removes the mask and then forms silicide regions on the gate conductor and the source and drain regions.

Abstract: An integrated BiCMOS semiconductor circuit has active moat areas in silicon. The active moat areas include electrically active components of the semiconductor circuit, which comprise active window structures for base and/or emitter windows. The integrated BiCMOS semiconductor circuit has zones where silicon is left to form dummy moat areas which do not include electrically active components, and has isolation trenches to separate the active moat areas from each other and from the dummy moat areas. The dummy moat areas comprise dummy window structures having geometrical dimensions and shapes similar to those of the active window structures for the base and/or emitter windows.

Abstract: A gate structure includes a substrate, a gate dielectric layer, a first conductive layer, a second conductive layer, a cap layer and a first insulating spacer. The gate dielectric layer is disposed on the substrate. The first conductive layer is disposed on the gate dielectric layer and has an opening. A part of the second conductive layer is disposed in the opening. The second conductive layer has an extrusion that protrudes above the opening of the first conductive layer. The extrusion has a cross-sectional width less than the width of the second conductive layer inside the opening. The cap layer is disposed on the extrusion. The first insulating spacer is disposed on a part of the first conductive layer and covers the sidewalls of the extrusion. The inclusion of the extrusion in the second conductive layer decreases the resistance of the gate structure and promotes the efficiency of the device.

Abstract: Methods of forming a transistor having integrated metal silicide transistor gate electrode on a semiconductor assembly are described. The transistor gate is partially fabricated by reacting the metal with epitaxial silicon while residing in a trench to form metal silicide. A transistor gate isolation capping layer is formed in the trench and on the metal silicide. Optional trench spacers can be added to reduce the critical dimension restraints of a given fabrication process and thus form a transistor having smaller feature sizes than the critical dimension.

Abstract: A gate electrode made of semiconductor is formed on the partial surface area of a semiconductor substrate. A mask member is formed on the surface of the semiconductor substrate in an area adjacent to the gate electrode. Impurities are implanted into the gate electrode. After impurities are implanted, the mask member is removed. Source and drain regions are formed by implanting impurities into the surface layer of the semiconductor substrate on both sides of the gate electrode. It is possible to reduce variations of cross sectional shape of gate electrodes and set an impurity concentration of the gate electrode independently from an impurity concentration of the source and drain regions.

Abstract: A method for fabricating a transistor of semiconductor is disclosed.

Abstract: Semiconductor processing methods of forming integrated circuitry are described. In one embodiment, memory circuitry and peripheral circuitry are formed over a substrate. The peripheral circuitry comprises first and second type MOS transistors. Second type halo implants are conducted into the first MOS transistors in less than all of the peripheral MOS transistors of the first type. In another embodiment, a plurality of n-type transistor devices are formed over a substrate and comprise memory array circuitry and peripheral circuitry. A least some of the individual peripheral circuitry n-type transistor devices are partially masked, and a halo implant is conducted for unmasked portions of the partially masked peripheral circuitry n-type transistor devices. In yet another embodiment, at least a portion of only one of the source and drain regions is masked, and at least a portion of the other of the source and drains regions is exposed for at least some of the peripheral circuitry n-type transistor devices.