Abstract: A semiconductor device includes a first type region including a first conductivity type and a second type region including a second conductivity type. The semiconductor device includes a channel region extending between the first type region and the second type region. The semiconductor device includes a gate electrode surrounding at least some of the channel region. A first gate edge of the gate electrode is separated a first distance from a first type region edge of the first type region and a second gate edge of the gate electrode is separated a second distance from a second type region edge of the second type region. The first distance is less than the second distance.

Abstract: The present disclosure relate to an integrated chip having long-channel and short-channel transistors having channel regions with different doping profiles. In some embodiments, the integrated chip includes a first gate electrode arranged over a first channel region having first length, and a second gate electrode arranged over a second channel region having a second length greater than the first length. The first channel region and the second channel region have a dopant profile, respectively along the first length and the second length, which has a dopant concentration that is higher by edges than in a middle of the first channel region and the second channel region. The dopant concentration is also higher by the edges of the first channel region than by the edges of the second channel region.

Abstract: Some embodiments of the present disclosure relate to an implant that improves long-channel transistor performance with little to no impact on short-channel transistor performance. To mitigate DIBL, both long-channel and short-channel transistors on a substrate are subjected to a halo implant. While the halo implant improves short-channel transistor performance, it degrades long-channel transistor performance. Therefore, a counter-halo implant is performed on the long-channel transistors only to restore their performance. To achieve this, the counter-halo implant is performed at an angle that introduces dopant impurities near the source/drain regions of the long-channel transistors to counteract the effects of the halo implant, while the counter-halo implant is simultaneously shadowed from reaching the channel of the short-channel transistors.

Abstract: The present disclosure relates to a transistor device having epitaxial source and drain regions with dislocation stress memorization (DSM) regions that provide stress to an epitaxial channel region, and an associated method of formation. The transistor device has an epitaxial stack disposed over a semiconductor substrate, and a gate structure disposed over the epitaxial stack. A channel region extends below the gate structure between epitaxial source and drain regions located on opposing sides of the gate structure. First and second dislocation stress memorization (DSM) regions have a stressed lattice that generates stress within the channel region. The first and second DSM regions respectively extend from below the epitaxial source region to a first location within the epitaxial source region from below the epitaxial drain region to a second location within the epitaxial drain region. Using the first and second DSM regions to stress the channel region, improves device performance.

Abstract: The present disclosure provides a semiconductor structure includes a gate structure disposed over a substrate, wherein the gate structure includes a high-k dielectric layer and a work function structure. The high-k dielectric layer includes a base portion and a side portion, the side portion is extended from an end of the base portion, the side portion is substantially orthogonal to the base portion. The work function structure includes a first metal disposed over the high-k dielectric layer and a second metal disposed over the first metal and including a bottom portion and a sidewall portion extended from an end of the bottom portion, wherein the first metal includes different materials from the second metal, and a length of an interface between the sidewall portion and the bottom portion to a length of the bottom portion within the high-k dielectric layer is in a predetermined ratio.

Abstract: The present disclosure relates to a transistor device having an epitaxial carbon layer and/or a carbon implantation region that provides for a low variation of voltage threshold, and an associated method of formation. In some embodiments, the transistor device has an epitaxial region arranged within a recess within a semiconductor substrate. The epitaxial region has a carbon doped silicon epitaxial layer and a silicon epitaxial layer disposed onto the carbon doped silicon epitaxial layer. A gate structure is arranged over the silicon epitaxial layer. The gate structure has a gate dielectric layer disposed onto the silicon epitaxial layer and a gate electrode layer disposed onto the gate dielectric layer. A source region and a drain region are arranged on opposing sides of a channel region disposed below the gate structure.

Abstract: A semiconductor device includes a nanowire structure and a stressor. The nanowire structure includes a first channel section and a second channel section. The stressor subjects the first channel section to a first strain level and the second channel section to a second strain level greater than the first strain level. The difference between the second strain level and the first strain level is less than the second strain level.

Abstract: Some embodiments of the present disclosure relate to a transistor device formed in a semiconductor substrate containing dopant impurities of a first impurity type. The transistor device includes channel composed of a delta-doped layer comprising dopant impurities of the first impurity type, and configured to produce a peak dopant concentration within the channel. The channel further includes a layer of carbon-containing material overlying the delta-doped layer, and configured to prevent back diffusion of dopants from the delta-doped layer and semiconductor substrate. The channel also includes of a layer of substrate material overlying the layer of carbon-containing material, and configured to achieve steep retrograde dopant concentration profile a near a surface of the channel.

Abstract: The present disclosure relates to method of forming a transistor device having epitaxial source and drain regions with dislocation stress memorization (DSM) regions that provide stress to an epitaxial channel region, and an associated device. The method forms a first dislocation stress memorization (DSM) region and a second DSM region having stressed lattices within a substrate. The substrate is selectively etched to form a source cavity and a drain cavity extending from an upper surface of the substrate to positions contacting the first DSM region and the second DSM region. An epitaxial source is formed within the source cavity and an epitaxial drain region is formed within the drain cavity. A gate structure is formed over the substrate at a location laterally between the epitaxial source region and the epitaxial drain region.

Abstract: A method for improving analog gain in long channel devices associated with a semiconductor workpiece is provided. A gate oxide layer is formed on the semiconductor workpiece, and a plurality of gate structures are formed over the gate oxide layer, wherein a first pair of the plurality of gate structures define a short channel device region and a second pair of the plurality of gate structures define a long channel device region. A first ion implantation with a first dopant is performed at a first angle, wherein the first dopant is one of an n-type dopant and a p-type dopant. A second ion implantation with a second dopant is performed at a second angle, wherein the second angle is greater than the first angle. The second dopant is one or an n-type dopant and a p-type dopant that is opposite of the first dopant, and a height of the plurality of gate structures and the second angle generally prevents the second ion implantation from implanting ions into the short channel device region.

Abstract: The present disclosure provides a semiconductor structure includes a gate structure disposed over a substrate, wherein the gate structure includes a high-k dielectric layer and a work function structure. The high-k dielectric layer includes a base portion and a side portion, the side portion is extended from an end of the base portion, the side portion is substantially orthogonal to the base portion. The work function structure includes a first metal disposed over the high-k dielectric layer and a second metal disposed over the first metal and including a bottom portion and a sidewall portion extended from an end of the bottom portion, wherein the first metal includes different materials from the second metal, and a length of an interface between the sidewall portion and the bottom portion to a length of the bottom portion within the high-k dielectric layer is in a predetermined ratio.

Abstract: Some embodiments of the present disclosure provide a semiconductor structure including a substrate and an epitaxy region partially disposed in the substrate. The epitaxy region includes a substance with a lattice constant that is larger than a lattice constant of the substrate. The concentration profile of a substance in the epitaxy region is monotonically increasing from a bottom portion of the epitaxy region to a of the epitaxy region. A first layer of the epitaxy region has a height to width ratio of about 2. The first layer is a layer positioned closest to the substrate, and the first layer has an average concentration of the substance from about 20 to about 32 percent. A second layer disposed over the first layer. The second layer has a bottom portion with a concentration of the substance from about 27 percent to about 37 percent.

Abstract: The disclosure provides a method of forming a transistor. In this method, a dummy gate structure is formed over a semiconductor substrate. Source/drain regions are then formed in the semiconductor substrate such that a channel region, which is arranged under the dummy gate structure in the semiconductor substrate, separates the source/drains from one another. After the source/drain regions have been formed, the dummy gate structure is removed. After the dummy gate structure has been removed, a surface region of the channel region is removed to form a channel region recess. A replacement channel region is then epitaxially grown in the channel region recess.

Abstract: Some embodiments of the present disclosure provide a semiconductor structure, including a substrate and a regrowth region. The substrate is made of a first material with a first lattice constant, and the regrowth region is made of the first material and a second material, having a lattice constant different from the first lattice constant. The regrowth region is partially positioned in the substrate. The regrowth region has a “tip depth” measured vertically from a surface of the substrate to a widest vertex of the regrowth region, and the tip depth being less than 10 nm. The regrowth region further includes a top layer substantially made of the first material, and the top layer has substantially the first lattice constant.

Abstract: The present disclosure relates to a method of forming a transistor device having a carbon implantation region that provides for a low variation of voltage threshold, and an associated apparatus. The method is performed by forming a well region within a semiconductor substrate. The semiconductor substrate is selectively etched to form a recess within the well region. After formation of the recess, a carbon implantation is selectively performed to form a carbon implantation region within the semiconductor substrate at a position underlying the recess. An epitaxial growth is then performed to form one or more epitaxial layers within the recess at a position overlying the carbon implantation region. Source and drain regions are subsequently formed within the semiconductor substrate such that a channel region, comprising the one or more epitaxial layers, separates the source/drains from one another.

Abstract: A semiconductor device includes a gate structure located on a substrate; and a raised source/drain region adjacent to the gate structure. An interface is between the gate structure and the substrate. The raised source/drain region includes a stressor layer providing strain to a channel under the gate structure; and a silicide layer in the stressor layer. The silicide layer extends from a top surface of the raised source/drain region and ends below the interface by a predetermined depth. The predetermined depth allows the stressor layer to maintain the strain of the channel.

Abstract: The present disclosure provides many different embodiments of an IC device. The IC device includes a gate stack disposed over a surface of a substrate and a spacer disposed along a sidewall of the gate stack. The spacer has a tapered edge that faces the surface of the substrate while tapering toward the gate stack. Therefore the tapered edge has an angle with respect to the surface of the substrate.

Abstract: A semiconductor device with variable channel strain is provided. The semiconductor device comprises a nanowire structure formed as a channel between a source region and a drain region. The nanowire structure has a first channel section subjected to a first strain level and joined with a second channel section subjected to a second strain level different from the first strain level. The first channel section is coupled adjacent to the drain region and the second channel section is coupled adjacent to the source region. The semiconductor device further comprises a gate region that has a first strain section and a second strain section. The first strain section is configured to cause the first channel section to be subjected to the first strain level and the second strain section is configured to cause the second channel section to be subjected to the second strain level.

Abstract: Some embodiments of the present disclosure relate to a transistor device formed in a semiconductor substrate containing dopant impurities of a first impurity type. The transistor device includes channel composed of a delta-doped layer comprising dopant impurities of the first impurity type, and configured to produce a peak dopant concentration within the channel. The channel further includes a layer of carbon-containing material overlying the delta-doped layer, and configured to prevent back diffusion of dopants from the delta-doped layer and semiconductor substrate. The channel also includes of a layer of substrate material overlying the layer of carbon-containing material, and configured to achieve steep retrograde dopant concentration profile a near a surface of the channel.

Abstract: A semiconductor device and method of forming the same are described. A semiconductor device includes an active area adjacent a channel in a semiconductor composite. The active area includes a first active area layer having a first dopant concentration, a second active area layer having a second dopant concentration over the first active area layer, and a third active area layer having a third dopant concentration, over the second active area. The third dopant concentration is greater than the second dopant concentration, and the second dopant concentration is greater than the first dopant concentration. The channel includes a second channel layer comprising carbon over a first channel layer and a third channel layer over the second channel layer. The active area configuration improves drive current and reduces contact resistance, and the channel configuration increases short channel control, as compared to a semiconductor device without the active area and channel configuration.