Abstract: In accordance with a preferred embodiment of the present invention, a silicon-on-insulator (SOI) chip includes a silicon layer of a predetermined thickness overlying an insulator layer. A multiple-gate fully-depleted SOI MOSFET including a strained channel region is formed on a first portion of the silicon layer. A planar SOI MOSFET including a strained channel region formed on another portion of the silicon layer. For example, the planar SOI MOSFET can be a planar fully-depleted SOI (FD-SOI) MOSFET or the planar SOI MOSFET can be a planar partially-depleted SOI (PD-SOI) MOSFET.

Abstract: A semiconductor device formed on a semiconductor substrate and a method of forming the same. In one embodiment, the semiconductor device includes a gate over the semiconductor substrate and a dielectric liner on a sidewall of the gate. The semiconductor device also includes an extension spacer adjacent and extending laterally beyond the dielectric liner along the semiconductor substrate. The semiconductor device further includes a source/drain located below an upper surface of the semiconductor substrate and adjacent a channel region under the gate. The source/drain extends under the dielectric liner and the extension spacer. The semiconductor device still further includes a silicide region over a portion of the source/drain and extending laterally beyond the extension spacer along the semiconductor substrate. Thus, the extension spacer is interposed between the dielectric liner and the silicide region located over a portion of the source/drain.

Abstract: A method comprises providing a semiconductor alloy layer on a semiconductor substrate, forming a gate structure on the semiconductor alloy layer, forming source and drain regions in the semiconductor substrate on both sides of the gate structure, removing at least a portion of the semiconductor alloy layer overlying the source and drain regions, and forming a metal silicide region over the source and drain regions.

Abstract: A method and system for isolation trenches includes forming isolation trenches in a semiconductor substrate, filling the trenches with a filler material, creating voids near top edges of the trenches and annealing by a gaseous ambient to reflow the edges of the trenches causing the edges to become rounded and overhang the trench. The filler material may be a dielectric. Transistors are then formed in close proximity to the trenches and may include source/drain regions formed in the rounded portion of the semiconductor substrate that overhangs the trench.

Abstract: A method of improving the carrier mobility of a transistor is presented. A trench is formed in a substrate. The trench is filled with a dielectric. A CMOS transistor is formed adjacent to the trench. A silicide layer is formed on the source/drain region. After the step of forming the silicide layer, a recess is formed by etching the dielectric so that the surface of the dielectric is substantially lower than the surface of the substrate. Recessing the STI causes the removal of the compressive stress applied to the channel region by the STI material. A contact etch stop layer (CESL) is formed over the gate electrode, spacers, source/drain region and the dielectric. The CESL applies a desired stress to the channel region. Trench liners may optionally be formed to provide a stress to the channel region. A trench spacer may optionally be formed in the STI recess.

Abstract: A method provides for dicing a wafer having a base material with a diamond structure. The wafer first undergoes a polishing process, in which a predetermined portion of the wafer is polished away from its back side. The wafer is then diced through at least one line along a direction at a predetermined offset angle from a natural cleavage direction of the diamond structure. A wafer is produced with one or more dies formed thereon with at least one of its edges at an offset angle from a natural cleavage direction of a diamond structure of a base material forming the wafer. At least one dicing line has one or more protection elements for protecting the dies from undesired cracking while the wafer is being diced along the dicing line.

Abstract: Embodiments of the invention provide a semiconductor device and a method of manufacture. MOS devices along with their polycrystalline or amorphous gate electrodes are fabricated such that the intrinsic stress within the gate electrode creates a stress in the channel region between the MOS source/drain regions. Embodiments include forming an NMOS device and a PMOS device after having converted a portion of the intermediate NMOS gate electrode layer to an amorphous layer and then recrystallizing it before patterning to form the electrode. The average grain size in the NMOS recrystallized gate electrode is smaller than that in the PMOS recrystallized gate electrode. In another embodiment, the NMOS device comprises an amorphous gate electrode.

Abstract: A method comprises providing a semiconductor alloy layer on a semiconductor substrate, forming a gate structure on the semiconductor alloy layer, forming source and drain regions in the semiconductor substrate on both sides of the gate structure, removing at least a portion of the semiconductor alloy layer overlying the source and drain regions, and forming a metal silicide region over the source and drain regions.

Abstract: A method of manufacturing a microelectronic device includes forming a p-channel transistor on a silicon substrate by forming a poly gate structure over the substrate and forming a lightly doped source/drain region in the substrate. An oxide liner and nitride spacer are formed adjacent to opposing side walls of the poly gate structure and a recess is etched in the semiconductor substrate on opposing sides of the oxide liner. Raised SiGe source/drain regions are formed on either side of the oxide liner and slim spacers are formed over the oxide liner. A hard mask over the poly gate structure is used to protect the poly gate structure during the formation of the raised SiGe source/drain regions. A source/drain dopant is then implanted into the substrate including the SiGe regions.

Abstract: A semiconductor structure having a recessed active region and a method for forming the same are provided. The semiconductor structure comprises a first and a second isolation structure having an active region therebetween. The first and second isolation structures have sidewalls with a tilt angle of substantially less than 90 degrees. The active region is recessed. By recessing the active region, the channel width is increased and device drive current is improved.

Abstract: A method of improving transistor carrier mobility by adjusting stress through recessing shallow trench isolation is presented. A trench is formed in a substrate. The trench is filled with a dielectric. A CMOS transistor is formed adjacent to the trench. A silicide layer is formed on the source/drain region. A recess is formed by etching the dielectric so that the surface of the dielectric is substantially lower than the surface of the substrate. Recessing the STI removes the compressive stress applied to the channel region by the STI material. A contact etch stop layer (CESL) is formed over the gate electrode, spacers, source/drain regions and the dielectric. The CESL applies a desired stress to the channel region. Trench liners are optionally formed to provide a stress to the channel region. A spacer can optionally be formed in the STI recess.

Abstract: A method is disclosed for dicing a wafer having a base material with a diamond structure. The wafer first undergoes a polishing process, in which a predetermined portion of the wafer is polished away from its back side. The wafer is then diced through at least one line along a direction at a predetermined offset angle from a natural cleavage direction of the diamond structure.

Abstract: An offset spacer for CMOS transistors and a method of manufacture is provided. A gate electrode is formed on a substrate, and an offset mask layer is formed over the surface of the gate electrode and the substrate. The offset mask may be formed of an oxide layer and acts as a mask during implanting, such as pocket implants and lightly-doped drain implants. A second implant spacer may be formed on top of the offset mask layer adjacent the gate electrode, and another implant process may be performed to form deeply-doped drain regions.

Abstract: A semiconductor light emitting device and a method to form the same are disclosed. The device has at least one porous or low density dielectric region formed in or on top of a bottom electrode, at least one top electrode on the porous or low density dielectric region, and one or more color filters placed above the top electrode, wherein the porous or low density dielectric region contains light emitting nanocrystal materials.

Abstract: A phase change memory device with a reduced phase change volume and lower drive current and a method for forming the same are provided. The method includes forming a bottom insulating layer comprising a bottom electrode contact, forming a bottom electrode film on the bottom electrode contact, forming an anti-reflective coating (ARC) film on the bottom electrode film, patterning and etching the ARC film and the bottom electrode film to form a bottom electrode comprising a side edge, and forming a phase change material portion on the ARC film and the bottom insulating layer, wherein the phase change material portion physically contacts the side edge of the bottom electrode. The method further includes forming a top electrode on the phase change material portion, and forming a top electrode contact on the top electrode.

Abstract: A CMOS structure including a Slim spacer and method for forming the same to reduce an S/D electrical resistance and improve charge mobility in a channel region, the method including providing a semiconductor substrate including a polysilicon gate structure including at least one overlying hardmask layer; forming spacers selected from the group consisting of oxide/nitride and oxide/nitride oxide layers adjacent the polysilicon gate structure; removing the at least one overlying hardmask layer to expose the polysilicon gate structure; carrying out an ion implant process; carrying out at least one of a wet and dry etching process to reduce the width of the spacers; and, forming at least one dielectric layer over the polysilicon gate structure and spacers in one of tensile and compressive stress.

Abstract: A method of manufacturing a microelectronic device includes forming a p-channel transistor on a silicon substrate by forming a poly gate structure over the substrate and forming a lightly doped source/drain region in the substrate. An oxide liner and nitride spacer are formed adjacent to opposing side walls of the poly gate structure and a recess is etched in the semiconductor substrate on opposing sides of the oxide liner. Raised SiGe source/drain regions are formed on either side of the oxide liner and slim spacers are formed over the oxide liner. A hard mask over the poly gate structure is used to protect the poly gate structure during the formation of the raised SiGe source/drain regions. A source/drain dopant is then implanted into the substrate including the SiGe regions.

Abstract: A flash memory device includes a floating gate made of a multi-layered structure. The floating gate includes a hetero-pn junction which serves as a quantum well to store charge in the floating gate, thus increasing the efficiency of the device, allowing the device to be operable using lower voltages and increasing the miniaturization of the device. The floating gate may be used in n-type and p-type devices, including n-type and p-type fin-FET devices. The stored charge may be electrons or holes.

Abstract: A multi-level semiconductor device wiring interconnect structure and method of forming the same to improve electrical properties and reliability of wiring interconnects including an electromigration resistance and electrical resistance, the method including forming a dielectric insulating layer over a conductive portion; forming a via opening in closed communication with the conductive portion; forming a first barrier layer to line the via opening; forming a layer of AlCu according to a sputtering process to fill the via opening to form an AlCu via including a portion overlying the first dielectric insulating layer; and, photolithographically patterning and dry etching the portion to form an AlCu interconnect line over the AlCu via.

Abstract: A method for manufacturing a metal gate includes providing a substrate including a gate electrode located on the substrate. A plurality of layers is formed, including a first layer located on the substrate and the gate electrode and a second layer adjacent the first layer. The layers are etched to form a plurality of adjacent spacers, including a first spacer located on the substrate and adjacent the gate electrode and a second spacer adjacent the first spacer. The first spacer is then etched and a metal layer is formed on the device immediately adjacent to the gate electrode. The metal layer is then reacted with the gate electrode to form a metal gate.