Abstract: A FinFET and methods for forming a FinFET are disclosed. A method includes forming trenches in a semiconductor substrate to form a fin, depositing an insulating material within the trenches, and removing a portion of the insulating material to expose sidewalls of the fin. The method also includes recessing a portion of the exposed sidewalls of the fin to form multiple recessed surfaces on the exposed sidewalls of the fin, wherein adjacent recessed surfaces of the multiple recessed surfaces are separated by a lattice shift. The method also includes depositing a gate dielectric on the recessed portion of the sidewalls of the fin and depositing a gate electrode on the gate dielectric.

Abstract: A shallow trench isolation (STI) structure is formed on a substrate. Part of the STI structure is removed to form a first fin structure and a second fin structure extending above a support structure on the substrate. A first part of the STI structure is located between the first fin structure and the second fin structure and has a first top surface higher than an interface between the first fin structure and the support structure. A second part of the STI structure is located adjacent to the first fin structure and has a second top surface lower than the interface between the first fin structure and the support structure. An etching process is performed to remove part of the first fin structure and the second fin structure. Part of the support structure adjacent to the second part of the STI structure is removed during the etching process.

Abstract: Devices are described herein that include a first fin structure formed on a substrate. A second fin structure formed on the substrate. One or more gate structures are formed on the first fin structure and the second fin structure. A first in-fin source/drain region is associated with a first volume and is disposed between the first fin structure and the second fin structure. A fin-end source/drain region is associated with a second volume larger than the first volume, the first fin structure being disposed between the first in-fin source/drain region and the fin-end source/drain region. The gate structures, the first in-fin source/drain region, and the fin-end source/drain region are configured to form one or more transistors.

Abstract: FETs and methods for forming FETs are disclosed. A structure comprises a substrate, a gate dielectric and a gate electrode. The substrate comprises a fin, and the fin comprises an epitaxial channel region. The epitaxial channel has a major surface portion of an exterior surface. The major surface portion comprising at least one lattice shift, and the at least one lattice shift comprises an inward or outward shift relative to a center of the fin. The gate dielectric is on the major surface portion of the exterior surface. The gate electrode is on the gate dielectric.

Abstract: The present disclosure provides a quantum well fin field effect transistor (QWFinFET). The QWFinFET includes a semiconductor fin over a substrate and a combo quantum well (QW) structure over the semiconductor fin. The combo QW structure includes a QW structure over a top portion of the semiconductor fin and a middle portion of the semiconductor fin. The semiconductor fin and the QW comprise different semiconductor materials. The QWFinFET also includes a gate stack over the combo QW structure.

Abstract: An embodiment high electron mobility transistor (HEMT) includes a gate electrode over a semiconductor substrate and a multi-layer semiconductor cap over the semiconductor substrate and adjacent the gate electrode. The multi-layer semiconductor cap includes a first semiconductor layer and a second semiconductor layer comprising a different material than the first semiconductor layer. The first semiconductor layer is laterally spaced apart from the gate electrode by a first spacing, and the second semiconductor layer is spaced apart from the gate electrode by a second spacing greater than the first spacing.

Abstract: A method includes forming isolation regions in a semiconductor substrate, forming a first semiconductor strip between opposite portions of isolation regions, forming a second semiconductor strip overlying and contacting the first semiconductor strip, and performing a first recessing to recess the isolation regions. A portion of the second semiconductor strip over top surfaces of remaining portions of the isolation regions forms a semiconductor fin. A second recessing is performed to recess the isolation regions to extend the semiconductor fin downwardly, with an inter-diffusion region of the first semiconductor strip and the second semiconductor strip being exposed after the second recessing. The inter-diffusion region is then etched.

Abstract: An embodiment high electron mobility transistor (HEMT) includes a gate electrode over a semiconductor substrate and a multi-layer semiconductor cap over the semiconductor substrate and adjacent the gate electrode. The multi-layer semiconductor cap includes a first semiconductor layer and a second semiconductor layer comprising a different material than the first semiconductor layer. The first semiconductor layer is laterally spaced apart from the gate electrode by a first spacing, and the second semiconductor layer is spaced apart from the gate electrode by a second spacing greater than the first spacing.

Abstract: An embodiment is a method including forming an epitaxial portion over a substrate, the epitaxial portion including a III-V material. A damaged material layer being on at least one surface of the epitaxial portion. The method further including oxidizing at least outer surfaces of the damaged material layer to form an oxide layer, selectively removing the oxide layer, and repeating the oxidizing and the selectively removing steps while at least a portion of the damaged material layer remains on the epitaxial portion.

Abstract: An embodiment high electron mobility transistor (HEMT) includes a gate electrode over a semiconductor substrate and a multi-layer semiconductor cap over the semiconductor substrate and adjacent the gate electrode. The multi-layer semiconductor cap includes a first semiconductor layer and a second semiconductor layer comprising a different material than the first semiconductor layer. The first semiconductor layer is laterally spaced apart from the gate electrode by a first spacing, and the second semiconductor layer is spaced apart from the gate electrode by a second spacing greater than the first spacing.

Abstract: FETs and methods for forming FETs are disclosed. A structure comprises a substrate, a gate dielectric and a gate electrode. The substrate comprises a fin, and the fin comprises an epitaxial channel region. The epitaxial channel has a major surface portion of an exterior surface. The major surface portion comprising at least one lattice shift, and the at least one lattice shift comprises an inward or outward shift relative to a center of the fin. The gate dielectric is on the major surface portion of the exterior surface. The gate electrode is on the gate dielectric.

Abstract: A FinFET and methods for forming a FinFET are disclosed. A method includes forming trenches in a semiconductor substrate to form a fin, depositing an insulating material within the trenches, and removing a portion of the insulating material to expose sidewalls of the fin. The method also includes recessing a portion of the exposed sidewalls of the fin to form multiple recessed surfaces on the exposed sidewalls of the fin, wherein adjacent recessed surfaces of the multiple recessed surfaces are separated by a lattice shift. The method also includes depositing a gate dielectric on the recessed portion of the sidewalls of the fin and depositing a gate electrode on the gate dielectric.

Abstract: The present disclosure provides a quantum well fin field effect transistor (QWFinFET). The QWFinFET includes a semiconductor fin over a substrate and a combo quantum well (QW) structure over the semiconductor fin. The combo QW structure includes a QW structure over a top portion of the semiconductor fin and a middle portion of the semiconductor fin. The semiconductor fin and the QW comprise different semiconductor materials. The QWFinFET also includes a gate stack over the combo QW structure.

Abstract: FETs and methods for forming FETs are disclosed. A structure comprises a substrate, a gate dielectric and a gate electrode. The substrate comprises a fin, and the fin comprises an epitaxial channel region. The epitaxial channel has a major surface portion of an exterior surface. The major surface portion comprising at least one lattice shift, and the at least one lattice shift comprises an inward or outward shift relative to a center of the fin. The gate dielectric is on the major surface portion of the exterior surface. The gate electrode is on the gate dielectric.

Abstract: A method of forming a semiconductor device is provided. The method includes forming a recess in a substrate and forming a first dielectric layer in the recess. A portion of the first dielectric layer is removed. A second dielectric layer is formed over the first dielectric layer. A gate structure is formed over the second dielectric layer.

Abstract: A finFET and methods for forming a finFET are disclosed. A structure comprises a substrate, a fin, a gate dielectric, and a gate electrode. The substrate comprises the fin. The fin has a major surface portion of a sidewall, and the major surface portion comprises at least one lattice shift. The at least one lattice shift comprises an inward or outward shift relative to a center of the fin. The gate dielectric is on the major surface portion of the sidewall. The gate electrode is on the gate dielectric.

Abstract: A semiconductor device includes a fin feature in a substrate, a stack of semiconductor layers over the fin feature. Each of the semiconductor layers does not contact each other. The device also includes a semiconductor oxide layer interposed between the fin feature and the stack of the semiconductor layers. A surface of the semiconductor oxide layer contacts the fin feature and an opposite surface of the semiconductor oxide layer contacts a bottom layer of the stack of semiconductor layers. The device also includes a conductive material layer encircling each of the semiconductor layers and filling in spaces between each of two semiconductor layers.

Abstract: The present disclosure provides a quantum well fin field effect transistor (QWFinFET). The QWFinFET includes a semiconductor fin over a substrate and a combo quantum well (QW) structure over the semiconductor fin. The combo QW structure includes a QW structure over a top portion of the semiconductor fin and a middle portion of the semiconductor fin. The semiconductor fin and the QW comprise different semiconductor materials. The QWFinFET also includes a gate stack over the combo QW structure.

Abstract: A semiconductor device includes a substrate and a gate structure formed over the substrate. The semiconductor device further includes an insulator feature formed in the substrate. The insulator feature includes an insulating layer and a capping layer over the insulating layer.

Abstract: A method includes forming isolation regions in a semiconductor substrate, forming a first semiconductor strip between opposite portions of isolation regions, forming a second semiconductor strip overlying and contacting the first semiconductor strip, and performing a first recessing to recess the isolation regions. A portion of the second semiconductor strip over top surfaces of remaining portions of the isolation regions forms a semiconductor fin. A second recessing is performed to recess the isolation regions to extend the semiconductor fin downwardly, with an inter-diffusion region of the first semiconductor strip and the second semiconductor strip being exposed after the second recessing. The inter-diffusion region is then etched.