Abstract: The tunnel field-effect transistor includes a drain layer, a source layer, a channel layer, a metal gate layer, and a high-k dielectric layer. The drain and source layers are of opposite conductive types. The channel layer is disposed between the drain layer and the source layer. At least one of the drain layer, the channel layer, and the source layer has a substantially constant doping concentration. The metal gate layer is disposed around the channel layer. The high-k dielectric layer is disposed between the metal gate layer and the channel layer.

Abstract: A tunnel field-effect transistor and method fabricating the same are provided. The tunnel field-effect transistor includes a drain region, a source region with opposite conductive type to the drain region, a channel region disposed between the drain region and the source region, a metal gate layer disposed around the channel region, and a high-k dielectric layer disposed between the metal gate layer and the channel region.

Abstract: A device includes insulation regions over portions of a semiconductor substrate, and a III-V compound semiconductor region over top surfaces of the insulation regions, wherein the III-V compound semiconductor region overlaps a region between opposite sidewalls of the insulation regions. The III-V compound semiconductor region includes a first and a second III-V compound semiconductor layer formed of a first III-V compound semiconductor material having a first band gap, and a third III-V compound semiconductor layer formed of a second III-V compound semiconductor material between the first and the second III-V compound semiconductor layers. The second III-V compound semiconductor material has a second band gap lower than the first band gap. A gate dielectric is formed on a sidewall and a top surface of the III-V compound semiconductor region. A gate electrode is formed over the gate dielectric.

Abstract: A semiconductor devices and method of formation are provided herein. A semiconductor device includes a gate structure over a channel and an active region adjacent the channel. The active region includes a repaired doped region and a growth region over the repaired doped region. The repaired doped region includes a first dopant and a second dopant, where the second dopant is from the growth region. A method of forming a semiconductor device includes increasing a temperature during exposure to at least one of dopant(s) or agent(s) to form an active region adjacent a channel, where the active region includes a repaired doped region and a growth region over the repaired doped region.

Abstract: A fin field effect transistor (FinFET) including a first insulation region and a second insulation region and fin there between. A gate stack is disposed over a first portion of the fin. A strained source/drain material is disposed over a second portion of the fin. The strained source/drain material has a flat top surface extending over the first and second insulation regions. The first insulation region may include a tapered top surface.

Abstract: A method includes epitaxially growing a first III-V compound semiconductor, wherein the first III-V compound semiconductor is of p-type. The first III-V compound semiconductor is grown using precursors including a first precursor comprising Cp2Mg, and a second precursor comprising a donor impurity. A second III-V compound semiconductor is grown overlying and contacting the first III-V compound semiconductor. The second III-V compound semiconductor is of n-type.

Abstract: A fin field effect transistor (FinFET) including a first insulation region and a second insulation region and fin there between. A gate stack is disposed over a first portion of the fin. A strained source/drain material is disposed over a second portion of the fin. The strained source/drain material has a flat top surface extending over the first and second insulation regions. The first insulation region may include a tapered top surface.

Abstract: Structures and methods are provided for forming bottom source/drain contact regions for nanowire devices. A nanowire is formed on a substrate. The nanowire extends substantially vertically relative to the substrate and is disposed between a top source/drain region and a bottom source/drain region. A first dielectric material is formed on the bottom source/drain region. A second dielectric material is formed on the first dielectric material. A first etching process is performed to remove part of the first dielectric material and part of the second dielectric material to expose part of the bottom source/drain region. A second etching process is performed to remove part of the first dielectric material under the second dielectric material to further expose the bottom source/drain region. A first metal-containing material is formed on the exposed bottom source/drain region. Annealing is performed to form a bottom contact region.

Abstract: The present disclosure relates to a semiconductor device having a delta doped sheet layer within a transistor's source/drain region to reduce contact resistance, and an associated method. In some embodiments, a dielectric layer is disposed over the transistor. A trench is disposed through the dielectric layer to the source/drain region and a conductive contact is disposed in the trench. The source/drain region comprises a delta doped sheet layer with a doping concentration that is higher than rest of the source/drain region.

Abstract: An embodiment is a method. A first III-V compound semiconductor is epitaxially grown in a trench on a substrate, and the epitaxial growth is performed in a chamber. The first III-V compound semiconductor has a first surface comprising a facet. After the epitaxial growth, the first surface of the first III-V compound semiconductor is etched to form an altered surface of the first III-V compound semiconductor. Etching the first surface is performed in the chamber in situ. A second III-V compound semiconductor is epitaxially grown on the altered surface of the first III-V compound semiconductor. The epitaxial growth of the first III-V compound semiconductor may be performed in a MOCVD chamber, and the etch may use an HCl gas. Structures resulting from methods are also disclosed.

Abstract: A method of fabricating a fin field effect transistor (FinFET) including forming a first insulation region and a second insulation region and fin there between. The method further includes forming a gate stack over a portion of the fin and over a portion of the first and second insulation regions. The method further includes tapering the top surfaces of the first and second insulation regions not covered by the gate stack.

Abstract: A semiconductor device having light-emitting diodes (LEDs) formed on a concave textured substrate is provided. A substrate is patterned and etched to form recesses. A separation layer is formed along the bottom of the recesses. An LED structure is formed along the sidewalls and, optionally, along the surface of the substrate between adjacent recesses. In these embodiments, the surface area of the LED structure is increased as compared to a planar surface. In another embodiment, the LED structure is formed within the recesses such that the bottom contact layer is non-conformal to the topology of the recesses. In these embodiments, the recesses in a silicon substrate result in a cubic structure in the bottom contact layer, such as an n-GaN layer, which has a non-polar characteristic and exhibits higher external quantum efficiency.

Abstract: A method for forming a double step surface on a semiconductor substrate includes, with an etching process used in a Metal-Organic Chemical Vapor Deposition (MOCVD) process, forming a rough surface on a region of a semiconductor substrate. The method further includes, with an annealing process used in the MOCVD process, forming double stepped surface on the region of the semiconductor substrate.

Abstract: A method of fabricating a fin field effect transistor (FinFET) including forming a first insulation region and a second insulation region and fin there between. The method further includes forming a gate stack over a portion of the fin and over a portion of the first and second insulation regions. The method further includes tapering the top surfaces of the first and second insulation regions not covered by the gate stack.

Abstract: A method includes epitaxially growing a first III-V compound semiconductor, wherein the first III-V compound semiconductor is of p-type. The first III-V compound semiconductor is grown using precursors including a first precursor comprising Cp2Mg, and a second precursor comprising a donor impurity. A second III-V compound semiconductor is grown overlying and contacting the first III-V compound semiconductor. The second III-V compound semiconductor is of n-type.

Abstract: A semiconductor devices and method of formation are provided herein. A semiconductor device includes a gate structure over a channel and an active region adjacent the channel. The active region includes a repaired doped region and a growth region over the repaired doped region. The repaired doped region includes a first dopant and a second dopant, where the second dopant is from the growth region. A method of forming a semiconductor device includes increasing a temperature during exposure to at least one of dopant(s) or agent(s) to form an active region adjacent a channel, where the active region includes a repaired doped region and a growth region over the repaired doped region.

Abstract: A method includes epitaxially growing a first III-V compound semiconductor, wherein the first III-V compound semiconductor is of p-type. The first III-V compound semiconductor is grown using precursors including a first precursor comprising Cp2Mg, and a second precursor comprising a donor impurity. A second III-V compound semiconductor is grown overlying and contacting the first III-V compound semiconductor. The second III-V compound semiconductor is of n-type.

Abstract: Structures and methods are provided for forming bottom source/drain contact regions for nanowire devices. A nanowire is formed on a substrate. The nanowire extends substantially vertically relative to the substrate and is disposed between a top source/drain region and a bottom source/drain region. A first dielectric material is formed on the bottom source/drain region. A second dielectric material is formed on the first dielectric material. A first etching process is performed to remove part of the first dielectric material and part of the second dielectric material to expose part of the bottom source/drain region. A second etching process is performed to remove part of the first dielectric material under the second dielectric material to further expose the bottom source/drain region. A first metal-containing material is formed on the exposed bottom source/drain region. Annealing is performed to form a bottom contact region.

Abstract: A fin field effect transistor including a first insulation region and a second insulation region over a top surface of a substrate. The first insulation region includes tapered top surfaces, and the second insulation region includes tapered top surfaces. The fin field effect transistor further includes a fin extending above the top surface between the first insulation region and the second insulation region. The fin includes a first portion having a top surface below the tapered top surfaces of the first insulation region. The fin includes a second portion having a top surface above the tapered top surfaces of the first insulation region.

Abstract: A device includes insulation regions over portions of a semiconductor substrate, and a III-V compound semiconductor region over top surfaces of the insulation regions, wherein the III-V compound semiconductor region overlaps a region between opposite sidewalls of the insulation regions. The III-V compound semiconductor region includes a first and a second III-V compound semiconductor layer formed of a first III-V compound semiconductor material having a first band gap, and a third III-V compound semiconductor layer formed of a second III-V compound semiconductor material between the first and the second III-V compound semiconductor layers. The second III-V compound semiconductor material has a second band gap lower than the first band gap. A gate dielectric is formed on a sidewall and a top surface of the III-V compound semiconductor region. A gate electrode is formed over the gate dielectric.