Abstract: A method of making a semiconductor device includes depositing a TiN layer over a substrate. The method further includes doping a first portion of the TiN layer using an oxygen-containing plasma treatment. The method further includes doping a second portion of the TiN layer using a nitrogen-containing plasma treatment, wherein the second portion of the TiN layer directly contacts the first portion of the TiN layer. The method further includes forming a first metal gate electrode over the first portion of the TiN layer. The method further includes forming a second metal gate electrode over the second portion of the TiN layer, wherein the first metal gate electrode has a different work function from the second metal gate electrode, and the second metal gate electrode directly contacts the first metal gate electrode.

Abstract: A method of forming an integrated circuit includes forming a patterned mask layer on a material layer, wherein the patterned mask layer has a plurality of first features, and a first distance between adjacent first features of the plurality of first features. The method further includes patterning the material layer to form the first features in the material layer. The method further includes increasing the first distance between adjacent first features of the plurality of first features to a second distance. The method further includes treating portions of the material layer exposed by the patterned mask layer. The method further includes removing the patterned mask layer; and removing non-treated portions of the material layer.

Abstract: A device includes a substrate, a first fin, a second fin, a first isolation structure, a second isolation structure, and a gate structure. The first fin extends from a p-type region of the substrate. The second fin extends from an n-type region of the substrate. The first isolation structure is over the p-type region and adjacent to the first fin. The first isolation structure has a bottom surface and opposite first and second sidewalls connected to the bottom surface, a first round corner is between the bottom surface and the first sidewall of the first isolation structure, and the first sidewall is substantially parallel to the second sidewall. The second isolation structure is over the n-type region and adjacent to the first fin. The first isolation structure is deeper than the second isolation structure. The gate structure is over the first isolation structure and covering the first fin.

Abstract: A semiconductor device includes a dielectric fin between a first semiconductor channel and a second semiconductor channel. The semiconductor device includes a first gate structure. The first gate structure includes a first portion and a second portion separated from each other by the dielectric fin. The semiconductor device includes a first gate spacer that extends along sidewalls of the first portion of the first gate structure. The semiconductor device includes a second gate spacer that extends along sidewalls of the second portion of the first gate structure, respectively. At least one of the first gate spacer or second gate spacer has a first portion with a first thickness and a second portion with a second thickness less than the first thickness, and wherein the first portion is closer to the dielectric fin than the second portion.

Abstract: In many applications, the assessment of the internal structures of tubular structures (such as in medical imaging, blood vessels, bronchi, and colon) has become a topic of high interest. Many 3D visualization techniques, such as “fly-through” and curved planar reformation (CPR), have been used for visualization of the lumens for medical applications. However, all the existing visualization techniques generate highly distorted images of real objects. This invention provides direct manipulation based on the centerline of the object and visualization of the 3D internal structures of a tubular object without any noticeable distortion. For the first time ever, the lumens of a human colon is visualized as it is in reality. In many medical applications, this can be used for diagnosis, planning of surgery or stent placements, etc. and consequently improves the quality of healthcare significantly. The same technique can be used in many other applications.

Abstract: A method of forming a semiconductor device includes: forming a fin protruding above a substrate; forming isolation regions on opposing sides of the fin; forming a dummy gate electrode over the fin; removing lower portions of the dummy gate electrode proximate to the isolation regions, where after removing the lower portions, there is a gap between the isolation regions and a lower surface of the dummy gate electrode facing the isolation regions; filling the gap with a gate fill material; after filling the gap, forming gate spacers along sidewalls of the dummy gate electrode and along sidewalls of the gate fill material; and replacing the dummy gate electrode and the gate fill material with a metal gate.

Abstract: A method includes depositing a dummy gate dielectric layer over a semiconductor region, depositing a dummy gate electrode layer, and performing a first etching process. An upper portion of the dummy gate electrode layer is etched to form an upper portion of a dummy gate electrode. The method further includes forming a protection layer on sidewalls of the upper portion of the dummy gate electrode, and performing a second etching process. A lower portion of the dummy gate electrode layer is etched to form a lower portion of the dummy gate electrode. A third etching process is then performed to etch the lower portion of the dummy gate electrode using the protection layer as an etching mask. The dummy gate electrode is tapered by the third etching process. The protection layer is removed, and the dummy gate electrode is replaced with a replacement gate electrode.

Abstract: Semiconductor devices and methods of forming are described herein. The methods include depositing a dummy gate material layer over a fin etched into a substrate. A gate mask is then formed over the dummy gate material layer in a channel region of the fin. A dummy gate electrode is etched into the dummy gate material using the gate mask. A top spacer is then deposited over the gate mask and along sidewalls of a top portion of the dummy gate electrode. An opening is then etched through the remainder of the dummy gate material and through the fin. A bottom spacer is then formed along a sidewall of the opening and separates a bottom portion of the dummy gate electrode from the opening. A source/drain region is then formed in the opening and the dummy gate electrode is replaced with a metal gate stack.

Abstract: A complementary metal-oxide-semiconductor (CMOS) semiconductor device includes a substrate. The CMOS semiconductor device further includes an isolation region in the substrate. The CMOS semiconductor device further includes a P-metal gate electrode extending over the isolation region, wherein the P-metal gate electrode includes a first function metal and a TiN layer doped with a first material. The CMOS semiconductor device further includes an N-metal gate electrode extending over the isolation region, wherein the N-metal gate electrode includes a second function metal and a TiN layer doped with a second material different from the first material, a portion of the P-metal gate electrode is between a portion of the N-metal gate electrode and the substrate, and a portion of the TiN layer doped with the second material is between the portion of the P-metal gate electrode and the substrate.

Abstract: A lens for slowing or preventing the development of myopia includes an optical portion and a peripheral portion surrounding the optical portion. The distribution of the refractive power of the optical portion is expressed by an exponential growth function. Assume that a specific condition is satisfied. The farther away from the center of the lens, the greater the change in the refractive power. Thus, a defocus area is formed to control and prevent eye myopia. Besides, the distribution of refractive power can provide a larger visible area in order to effectively avoid visual instability caused by lens sliding.

Abstract: Provided is a cultivating material composition including a cultivating substrate and a bio-cellulose film, wherein the bio-cellulose film is in contact with the cultivating substrate, such that highly increased yield and quality of crops, a shorter harvest period, less water and nutrient sources, and low cost can be achieved.

Abstract: A method of forming a semiconductor device includes: forming a fin protruding above a substrate; forming isolation regions on opposing sides of the fin; forming a dummy gate electrode over the fin; removing lower portions of the dummy gate electrode proximate to the isolation regions, where after removing the lower portions, there is a gap between the isolation regions and a lower surface of the dummy gate electrode facing the isolation regions; filling the gap with a gate fill material; after filling the gap, forming gate spacers along sidewalls of the dummy gate electrode and along sidewalls of the gate fill material; and replacing the dummy gate electrode and the gate fill material with a metal gate.

Abstract: A method includes depositing a dummy gate dielectric layer over a semiconductor region, depositing a dummy gate electrode layer, and performing a first etching process. An upper portion of the dummy gate electrode layer is etched to form an upper portion of a dummy gate electrode. The method further includes forming a protection layer on sidewalls of the upper portion of the dummy gate electrode, and performing a second etching process. A lower portion of the dummy gate electrode layer is etched to form a lower portion of the dummy gate electrode. A third etching process is then performed to etch the lower portion of the dummy gate electrode using the protection layer as an etching mask. The dummy gate electrode is tapered by the third etching process. The protection layer is removed, and the dummy gate electrode is replaced with a replacement gate electrode.

Abstract: Semiconductor devices and methods of forming are described herein. The methods include depositing a dummy gate material layer over a fin etched into a substrate. A gate mask is then formed over the dummy gate material layer in a channel region of the fin. A dummy gate electrode is etched into the dummy gate material using the gate mask. A top spacer is then deposited over the gate mask and along sidewalls of a top portion of the dummy gate electrode. An opening is then etched through the remainder of the dummy gate material and through the fin. A bottom spacer is then formed along a sidewall of the opening and separates a bottom portion of the dummy gate electrode from the opening. A source/drain region is then formed in the opening and the dummy gate electrode is replaced with a metal gate stack.

Abstract: A semiconductor device and method are provided whereby a series of spacers are formed in a first region and a second region of a substrate. The series of spacers in the first region are patterned while the series of spacers in the second region are protected in order to separate the properties of the spacers in the first region from the properties of the spacers in the second region.

Abstract: A device including a gate stack over a semiconductor substrate having a pair of spacers abutting sidewalls of the gate stack. A recess is formed in the semiconductor substrate adjacent the gate stack. The recess has a first profile having substantially vertical sidewalls and a second profile contiguous with and below the first profile. The first and second profiles provide a bottle-neck shaped profile of the recess in the semiconductor substrate, the second profile having a greater width within the semiconductor substrate than the first profile. The recess is filled with a semiconductor material. A pair of spacers are disposed overly the semiconductor substrate adjacent the recess.

Abstract: A fin-type field-effect transistor (FinFET) device includes a plurality of fins formed over a substrate. The semiconductor device further includes a dielectric layer filled in a space between each fin and over a first portion of the plurality of fins and a dielectric trench formed in the dielectric layer. The dielectric trench has a vertical profile. The semiconductor device further includes a second portion of the plurality of fins recessed and exposed in the dielectric trench. The second portion of the plurality of fins have a rounded-convex-shape top profile.

Abstract: A semiconductor device includes a first semiconductor fin that is formed over a substrate and extends along a first lateral axis. The semiconductor device includes a second semiconductor fin that is also formed over the substrate and extends along the first lateral axis. At least a tip portion of the first semiconductor fin and at least a tip portion of the second semiconductor fin bend toward each other along a second lateral axis that is perpendicular to the first lateral axis.

Abstract: A method includes forming a dummy gate electrode on a semiconductor region, forming a first gate spacer on a sidewall of the dummy gate electrode, and removing an upper portion of the first gate spacer to form a recess, wherein a lower portion of the first gate spacer remains, filling the recess with a second gate spacer, removing the dummy gate electrode to form a trench, and forming a replacement gate electrode in the trench.

Abstract: A device includes a fin protruding from a semiconductor substrate; a gate stack over and along a sidewall of the fin; a gate spacer along a sidewall of the gate stack and along the sidewall of the fin; an epitaxial source/drain region in the fin and adjacent the gate spacer; and a corner spacer between the gate stack and the gate spacer, wherein the corner spacer extends along the sidewall of the fin, wherein a first region between the gate stack and the sidewall of the fin is free of the corner spacer, wherein a second region between the gate stack and the gate spacer is free of the corner spacer.