Abstract: A semiconductor device includes a semiconductor substrate having a first region and a second region. The first region includes a first set of fin structures, the first set of fin structures comprising a first set of epitaxial anti-punch-through features of a first conductivity type. The first region further includes a first set of transistors formed over the first set of fin structures. The second region includes a second set of fin structures, the second set of fin structures comprising a second set of epitaxial anti-punch-through features of a second conductivity type opposite to the first conductivity type. The second region further includes a second set of transistors formed over the second set of fin structures. The first set of epitaxial anti-punch-through features and the second set of epitaxial anti-punch-through features are substantially co-planar.

Abstract: A method for fabricating a semiconductor device includes forming a first gate stack over a first fin feature and second gate stack over a second fin feature, removing the first gate stack to form a first gate trench that exposes the first fin structure, removing the second gate stack to form a second gate trench that exposes the second fin feature, performing a high-pressure-anneal process to a portion of the first fin feature and forming a first high-k/metal gate (HK/MG) within the first gate trench over the portion of the first fin feature and a second HK/MG within the second gate trench over the second fin feature. Therefore the first HK/MG is formed with a first threshold voltage and the second HK/MG is formed with a second threshold voltage, which is different than the first threshold voltage.

Abstract: A method for fabricating a semiconductor device includes forming a relaxed semiconductor layer on a substrate, the substrate comprising an n-type region and a p-type region. The method further includes forming a tensile strained semiconductor layer on the relaxed semiconductor layer, etching a portion of the tensile strained semiconductor layer in the p-type region, forming a compressive strained semiconductor layer on the tensile strained semiconductor layer in the p-type region, forming a first gate in the n-type region and a second gate in the p-type region, and forming a first set of source/drain features adjacent to the first gate and a second set of source/drain features adjacent to the second gate. The second set of source/drain features are deeper than the first set of source/drain features.

Abstract: A method for fabricating a semiconductor device includes forming a relaxed semiconductor layer on a substrate, the substrate comprising an n-type region and a p-type region. The method further includes forming a tensile strained semiconductor layer on the relaxed semiconductor layer, etching a portion of the tensile strained semiconductor layer in the p-type region, forming a compressive strained semiconductor layer on the tensile strained semiconductor layer in the p-type region, forming a first gate in the n-type region and a second gate in the p-type region, and forming a first set of source/drain features adjacent to the first gate and a second set of source/drain features adjacent to the second gate. The second set of source/drain features are deeper than the first set of source/drain features.

Abstract: A FinFET device and method for fabricating a FinFET device is disclosed. An exemplary FinFET device includes a semiconductor substrate; a fin structure disposed over the semiconductor substrate; and a gate structure disposed over a portion of the fin structure. The gate structure traverses the fin structure and separates a source region and a drain region of the fin structure, the source and drain region defining a channel therebetween. The source and drain region of the fin structure include a strained source and drain feature. The strained source feature and the strained drain feature each include: a first portion having a first width and a first depth; and a second portion disposed below the first portion, the second portion having a second width and a second depth. The first width is greater than the second width, and the first depth is less than the second depth.

Abstract: A semiconductor device includes a substrate having a first region and a second region, an n-type transistor in the first region, the n-type transistor comprising a first set of source/drain features, and a p-type transistor in the second region, the p-type transistor comprising a second set of source/drain features. The second set of source/drain features extend deeper than the first set of source/drain features.

Abstract: A method for manufacturing a semiconductor device includes forming a fin structure over a substrate and forming a first gate structure over a first portion of the fin structure. A first nitride layer is formed over a second portion of the fin structure. The first nitride layer is exposed to ultraviolet radiation. Source/drain regions are formed at the second portion of the fin structure.

Abstract: A method includes providing a plurality of semiconductor fins parallel to each other, and includes two edge fins and a center fin between the two edge fins. A middle portion of each of the two edge fins is etched, and the center fin is not etched. A gate dielectric is formed on a top surface and sidewalls of the center fin. A gate electrode is formed over the gate dielectric. The end portions of the two edge fins and end portions of the center fin are recessed. An epitaxy is performed to form an epitaxy region, wherein an epitaxy material grown from spaces left by the end portions of the two edge fins are merged with an epitaxy material grown from a space left by the end portions of the center fin to form the epitaxy region. A source/drain region is formed in the epitaxy region.

Abstract: A semiconductor device includes a substrate having a first region and a second region, an n-type transistor in the first region, the n-type transistor comprising a first set of source/drain features, and a p-type transistor in the second region, the p-type transistor comprising a second set of source/drain features. The second set of source/drain features extend deeper than the first set of source/drain features.

Abstract: A method includes providing a plurality of semiconductor fins parallel to each other, and includes two edge fins and a center fin between the two edge fins. A middle portion of each of the two edge fins is etched, and the center fin is not etched. A gate dielectric is formed on a top surface and sidewalls of the center fin. A gate electrode is formed over the gate dielectric. The end portions of the two edge fins and end portions of the center fin are recessed. An epitaxy is performed to form an epitaxy region, wherein an epitaxy material grown from spaces left by the end portions of the two edge fins are merged with an epitaxy material grown from a space left by the end portions of the center fin to form the epitaxy region. A source/drain region is formed in the epitaxy region.

Abstract: A semiconductor device includes a semiconductor substrate having a first region and a second region. The first region includes a first set of fin structures, the first set of fin structures comprising a first set of epitaxial anti-punch-through features of a first conductivity type. The first region further includes a first set of transistors formed over the first set of fin structures. The second region includes a second set of fin structures, the second set of fin structures comprising a second set of epitaxial anti-punch-through features of a second conductivity type opposite to the first conductivity type. The second region further includes a second set of transistors formed over the second set of fin structures. The first set of epitaxial anti-punch-through features and the second set of epitaxial anti-punch-through features are substantially co-planar.

Abstract: A method of fabricating a semiconductor device includes forming a plurality of isolation features on a semiconductor substrate, thereby defining a first set of semiconductor features, performing an etching process on the first set of semiconductor features such that larger semiconductor features are etched deeper than smaller semiconductor features, after the etching process, forming anti-punch-through features on surfaces of the exposed features of the first set of semiconductor features, forming a semiconductor layer over the anti-punch-through features, and forming transistors on the semiconductor layer of each of the features of the first set of semiconductor features

Abstract: A method for fabricating a semiconductor device includes forming a first gate stack over a first fin feature and second gate stack over a second fin feature, removing the first gate stack to form a first gate trench that exposes the first fin structure, removing the second gate stack to form a second gate trench that exposes the second fin feature, performing an annealing process to change a composition of a portion of the first fin feature and forming a first high-k/metal gate (HK/MG) within the first gate trench over the portion of the first fin feature and a second HK/MG within the second gate trench over the second fin feature. Therefore the first HK/MG is formed with a first threshold voltage and the second HK/MG is formed with a second threshold voltage, which is different than the first threshold voltage.

Abstract: A method for fabricating a semiconductor device includes forming a first gate stack over a first fin feature and second gate stack over a second fin feature, removing the first gate stack to form a first gate trench that exposes the first fin structure, removing the second gate stack to form a second gate trench that exposes the second fin feature, performing a high-pressure-anneal process to a portion of the first fin feature and forming a first high-k/metal gate (HK/MG) within the first gate trench over the portion of the first fin feature and a second HK/MG within the second gate trench over the second fin feature. Therefore the first HK/MG is formed with a first threshold voltage and the second HK/MG is formed with a second threshold voltage, which is different than the first threshold voltage.

Abstract: A method for fabricating a semiconductor device includes forming a first gate stack over a first fin feature and second gate stack over a second fin feature, removing the first gate stack to form a first gate trench that exposes the first fin structure, removing the second gate stack to form a second gate trench that exposes the second fin feature, performing an annealing process to change a composition of a portion of the first fin feature and forming a first high-k/metal gate (HK/MG) within the first gate trench over the portion of the first fin feature and a second HK/MG within the second gate trench over the second fin feature. Therefore the first HK/MG is formed with a first threshold voltage and the second HK/MG is formed with a second threshold voltage, which is different than the first threshold voltage.

Abstract: Methods of forming semiconductor devices and structures thereof are disclosed. In some embodiments, a semiconductor device includes a substrate that includes fins. Gates are disposed over the fins, the gates being substantially perpendicular to the fins. A source/drain region is disposed on each of fins between two of the gates. A contact is coupled to the source/drain region between the two of the gates. The source/drain region comprises a first width, and the contact comprises a second width. The second width is substantially the same as the first width.

Abstract: A method and apparatus for estimating a height of an epitaxially grown semiconductor material in other semiconductor devices. The method includes epitaxially growing first, second, and third portions of semiconductor material on a first semiconductor device, measuring a height of the third portion of semiconductor material and a height of the first or second portion of semiconductor material, measuring a first saturation current through the first and second portions of semiconductor material, measuring a second saturation current through the first and third portions of semiconductor material, and preparing a model of the first saturation current relative to the height of the first or second portion of semiconductor material and the second saturation current relative to an average of the height of the first and third portions of semiconductor material. The model is used to estimate the height of an epitaxially grown semiconductor material in the other semiconductor devices.

Abstract: A method includes forming a gate stack including a gate electrode on a first semiconductor fin. The gate electrode includes a portion over and aligned to a middle portion of the first semiconductor fin. A second semiconductor fin is on a side of the gate electrode, and does not extend to under the gate electrode. The first and the second semiconductor fins are spaced apart from, and parallel to, each other. An end portion of the first semiconductor fin and the second semiconductor fin are etched. An epitaxy is performed to form an epitaxy region, which includes a first portion extending into a first space left by the etched first end portion of the first semiconductor fin, and a second portion extending into a second space left by the etched second semiconductor fin. A first source/drain region is formed in the epitaxy region.

Abstract: A method and apparatus for estimating a height of an epitaxially grown semiconductor material in other semiconductor devices. The method includes epitaxially growing first, second, and third portions of semiconductor material on a first semiconductor device, measuring a height of the third portion of semiconductor material and a height of the first or second portion of semiconductor material, measuring a first saturation current through the first and second portions of semiconductor material, measuring a second saturation current through the first and third portions of semiconductor material, and preparing a model of the first saturation current relative to the height of the first or second portion of semiconductor material and the second saturation current relative to an average of the height of the first and third portions of semiconductor material. The model is used to estimate the height of an epitaxially grown semiconductor material in the other semiconductor devices.

Abstract: A method and apparatus for estimating a height of an epitaxially grown semiconductor material in other semiconductor devices. The method includes epitaxially growing first, second, and third portions of semiconductor material on a first semiconductor device, measuring a height of the third portion of semiconductor material and a height of the first or second portion of semiconductor material, measuring a first saturation current through the first and second portions of semiconductor material, measuring a second saturation current through the first and third portions of semiconductor material, and preparing a model of the first saturation current relative to the height of the first or second portion of semiconductor material and the second saturation current relative to an average of the height of the first and third portions of semiconductor material. The model is used to estimate the height of an epitaxially grown semiconductor material in the other semiconductor devices.