Abstract: A stack for a semiconductor device and a method for making the stack are disclosed. The stack comprises a plurality of sacrificial layers in which each sacrificial layer comprises a first lattice parameter; and at least one channel layer comprising a second lattice parameter that is different from the first lattice parameter and in which each channel layer is disposed between and in contact with two sacrificial layers. The stack is formed on an underlayer in which a sacrificial layer is in contact with the underlayer. The underlayer comprises a third lattice parameter that substantially matches the lattice parameter that the plurality of sacrificial layers and the at least one channel layer would have if the plurality of sacrificial layers and the at least one channel layer were was allow to relax coherently.

Abstract: Exemplary embodiments provide for fabricating a nanosheet stack structure having one or more sub-stacks.

Abstract: A finFET device can include a source/drain contact recess having an optimal depth beyond which an incremental decrease in a spreading resistance value for a horizontal portion of a source/drain contact in the recess provided by increased depth may be less than an incremental increase in total resistance due to the increase in the vertical portion of the source/drain contact at the increased depth.

Abstract: A method of manufacturing a high-efficiency solar cell including an Indium, Gallium, Aluminum and Nitrogen (in a combination comprising InGaN, or InAlN, or InGaAlN) alloy which may be blended with a polyhedral oligomeric silsesquioxane (POSS) material, and which may include an absorption-enhancing layer including one of more of carbon nanotubes, quantum dots, and undulating or uneven surface topography.

Abstract: A high-efficiency solar cell including an Indium, Gallium, Aluminum and Nitrogen (in a combination comprising InGaN, or InAlN, or InGaAlN) alloy which may be blended with a polyhedral oligomeric silsesquioxane (POSS) material, and which may include an absorption-enhancing layer including one of more of carbon nanotubes, quantum dots, and undulating or uneven surface topography.

Abstract: Multi-layer fin field effect transistor devices and methods of forming the same are provided. The devices may include a fin shaped channel structure on a substrate. The channel structure may include stressor layers stacked on the substrate and a channel layer between the stressor layers, and the stressor layers may include a semiconductor material having a wide bandgap that is sufficient to confine carriers to the channel layer and having a lattice constant different from a lattice constant of the channel layer to induce stress in the channel layer. The devices may also include source/drain regions on respective first opposing sides of the channel structure and a gate on second opposing sides of the channel structure and between the source/drain regions.

Abstract: FinFET semiconductor devices and methods of forming the same are provided. The finFET semiconductor devices may include an insulator layer, a bottom semiconductor layer on the insulator layer, a channel fin on the bottom semiconductor layer, a source region on the bottom semiconductor layer and adjacent a first side of the channel fin, and a drain region on the bottom semiconductor layer and adjacent a second side of the channel fin opposite the first side.

Abstract: Exemplary embodiments provide for fabricating a biaxially strained nanosheet.

Abstract: A finFET device can include a high mobility semiconductor material in a fin structure that can provide a channel region for the finFET device. A source/drain recess can be adjacent to the fin structure and a graded composition epi-grown semiconductor alloy material, that includes a component of the high mobility semiconductor material, can be located in the source/drain recess.

Abstract: A field effect transistor (FET) includes a nanosheet stack having first and second stacked semiconductor channel layers. The first channel layer defines a channel region of a tunnel FET, and the second channel layer defines a channel region of a thermionic FET. Source and drain regions are provided on opposite sides of the nanosheet stack such that the first and second channel layers extend therebetween. A first portion of the source region adjacent the first channel layer and a second portion of the source region adjacent the second channel layer have opposite semiconductor conductivity types. Related fabrication and operating methods are also discussed.

Abstract: A damascene interconnect structure may be formed by forming a trench in an ILD. A diffusion barrier may be deposited on trench surfaces, followed by a first liner material. The first liner material may be removed from a bottom surface of the trench. A second liner material may be directionally deposited on the bottom. A conductive seed layer may be deposited on the first and second liner materials, and a conductive material may fill in the trench. A CMP process can remove excess material from the top of the structure. A damascene interconnect may include a dielectric having a trench, a first liner layer arranged on trench sidewalls, and a second liner layer arranged on a trench bottom. A conductive material may fill the trench. The first liner material may have low wettability and the second liner material may have high wettability with respect to the conductive material.

Abstract: Methods of forming a finFET are provided. The methods may include forming a fin-shaped channel region including indium (In) on a substrate, forming a deep source/drain region adjacent to the channel region on the substrate and forming a source/drain extension region between the channel region and the deep source/drain region. Opposing sidewalls of the source/drain extension region may contact the channel region and the deep source/drain region, respectively, and the source/drain extension region may include InyGa1?yAs, and y is in a range of about 0.3 to about 0.5.

Abstract: A field effect transistor includes a body layer having a strained crystalline semiconductor channel region, and a gate stack on the channel region. The gate stack includes a crystalline semiconductor gate layer that is lattice mismatched with the channel region, and a crystalline gate dielectric layer between the gate layer and the channel region. Related devices and fabrication methods are also discussed.

Abstract: A stack for a semiconductor device and a method for making the stack are disclosed. The stack comprises a plurality of sacrificial layers in which each sacrificial layer comprises a first lattice parameter; and at least one channel layer comprising a second lattice parameter that is different from the first lattice parameter and in which each channel layer is disposed between and in contact with two sacrificial layers. The stack is formed on an underlayer in which a sacrificial layer is in contact with the underlayer. The underlayer comprises a third lattice parameter that substantially matches the lattice parameter that the plurality of sacrificial layers and the at least one channel layer would have if the plurality of sacrificial layers and the at least one channel layer were was allow to relax coherently.

Abstract: Integrated circuit devices including strained channel regions and methods of forming the same are provided. The integrated circuit devices may include enhancement-mode field effect transistors. The enhancement-mode field effect transistors may include a quantum well channel region having a well thickness Tw sufficient to yield a strain-induced splitting of a plurality of equivalent-type electron conduction states therein to respective unequal energy levels including a lowermost energy level associated with a lowermost surface roughness scattering adjacent a surface of the channel region when, the surface is biased into a state of inversion.

Abstract: Multi-layer fin field effect transistor devices and methods of forming the same are provided. The devices may include a fin shaped channel structure on a substrate. The channel structure may include stressor layers stacked on the substrate and a channel layer between the stressor layers, and the stressor layers may include a semiconductor material having a wide bandgap that is sufficient to confine carriers to the channel layer and having a lattice constant different from a lattice constant of the channel layer to induce stress in the channel layer. The devices may also include source/drain regions on respective first opposing sides of the channel structure and a gate on second opposing sides of the channel structure and between the source/drain regions.

Abstract: A device may include a nanosheet field effect transistor (FET) that may include a substrate, a well that is doped with impurities at a surface of the substrate, a channel including a plurality of stacked nanosheets, a gate, a conductive material, and an isolation layer. Ones of the plurality of stacked nanosheets may include a semiconductor material that may be doped with impurities of the same conductivity type as the impurities of the well. The conductive material may be adjacent the plurality of nanosheets and may electrically connect ones of the plurality of nanosheets to the well. The isolation layer may electrically insulate the well from the workfunction metal.

Abstract: Exemplary embodiments are disclosed for a semi-metal transistor, comprising: a semi-metal contact region adjacent to a metal contact; at least one semiconductor terminal; and a semi-metal transition region connected between the contact region and the semiconductor terminal that transitions from a substantially zero gap semi-metal beginning at an interface of the contact region into a semiconductor with an energy band gap towards the semiconductor terminal.

Abstract: A high-efficiency solar cell including an Indium, Gallium, Aluminum and Nitrogen (in a combination comprising InGaN, or InAlN, or InGaAlN) alloy which may be blended with a polyhedral oligomeric silsesquioxane (POSS) material, and which may include an absorption-enhancing layer including one of more of carbon nanotubes, quantum dots, and undulating or uneven surface topography.

Abstract: A device may include a nanosheet field effect transistor (FET) that may include a substrate, a well that is doped with impurities at a surface of the substrate, a channel including a plurality of stacked nanosheets, a gate, a conductive material, and an isolation layer. Ones of the plurality of stacked nanosheets may include a semiconductor material that may be doped with impurities of the same conductivity type as the impurities of the well. The conductive material may be adjacent the plurality of nanosheets and may electrically connect ones of the plurality of nanosheets to the well. The isolation layer may electrically insulate the well from the workfunction metal.