Abstract: A liquid cooled semiconductor package and method for forming a liquid cooled semiconductor package is described. The device includes at least one semiconductor device mounted on a substrate. An impermeable housing is disposed on the substrate with an internal cavity. A liquid coolant is within the internal cavity such that the coolant immerses at least one semiconductor device.

Abstract: The present invention relates generally to semiconductor devices and more particularly, to a method of forming a replacement channel composed of a III-V compound semiconductor material in a doped layer of a III-V compound semiconductor substrate. The replacement channel may be formed by removing a portion of the doped layer located directly below a dummy gate stack that has been removed. A III-V compound semiconductor material may be grown in the removed the portion to form the replacement channel and a gate stack may be formed on the replacement channel.

Abstract: In one example, a method for fabricating a semiconductor device includes etching a layer of silicon to form a plurality of fins and growing layers of a semiconductor material directly on sidewalls of the plurality of fins, wherein the semiconductor material and surfaces of the sidewalls have different crystalline properties.

Abstract: An optoelectronic device includes an integrated circuit including electronic devices formed on a front side of a semiconductor substrate. A barrier layer is formed on a back side of the semiconductor substrate. A photonics layer is formed on the barrier layer. The photonics layer includes a core for transmission of light and a cladding layer encapsulating the core and including a different index of refraction than the core. The core is configured to couple light generated from a component of the optoelectronic device.

Abstract: A method for doping fins includes forming a first dopant layer in a first region and a second region to a height relative to a plurality of fins, forming a dielectric layer over the fins, removing the dielectric layer and the first dopant layer in the first region to expose a first fin in the first region, forming a second dopant layer over the first fin, and annealing to drive dopants into the fins from the first dopant layer in the second region and from the second dopant layer in the first region.

Abstract: Embodiments of the invention include a method for fabricating a semiconductor device, the resulting structure, and a method for using the resulting structure. A substrate is provided. A hard mask layer is patterned over at least a portion of the substrate. Regions of the substrate not protected by the hard mask are doped to form a source region and a drain region. The hard mask layer is removed. A dielectric layer is deposited on the substrate. An insulative layer is deposited on the dielectric layer. A nano-channel is created by etching a portion of the insulative layer which passes over the source region and the drain region.

Abstract: A plurality of mandrels is formed on a silicon substrate. The mandrels are spaced apart at a given pitch, wherein at least one of the plurality of mandrels is formed having a first width, and at least another one of the plurality of mandrels is formed having a second width, and wherein the first width is greater than the second width. At least one structure is formed by removing at least a portion of the plurality of mandrels in a sidewall image transfer process without using a cut mask.

Abstract: A structure includes an optoelectronic device having a Group IV substrate (e.g., Si); a buffer layer (e.g. SiGe) disposed on the substrate and a first distributed Bragg reflector (DBR) disposed on the buffer layer. The first DBR contains alternating layers of doped Group IV materials (e.g., alternating layers of SiyGe(1-y), where 0.8<y<1, and SizGe(1-z), where 0.2<z<0.4) that are substantially transparent to a wavelength of interest. The structure further includes a strained layer of a Group III-V material over the first DBR and a second DBR over the strained layer. The second DBR contains alternating layers of electrically conductive oxides (e.g., ITO/AZO) that are substantially transparent to the wavelength of interest. Embodiments of VCSELs and photodetectors can be derived from the structure. The strained layer of Group III-V material can be, for example, a thin layer of In0.53Ga0.47As having a thickness in a range of about 2 nm to about 5 nm.

Abstract: After forming a first sacrificial gate stack over a portion of a first semiconductor fin located in a logic device region of a substrate, and a second sacrificial gate stack over a portion of a second semiconductor fin located in a memory device region of the substrate, in which each of the first sacrificial gate stack and the second sacrificial gate stack includes, from bottom to top, a tunneling oxide portion, a floating gate electrode, a control oxide portion, a gate conductor and a gate cap, an entirety of the first sacrificial gate stack is removed to provide a first gate cavity, and only the gate cap and the gate conductor are removed from the second sacrificial gate stack to provide a second gate cavity. Next, a high-k gate dielectric and a gate electrode are formed within each of the first gate cavity and the second gate cavity.

Abstract: A method of making a vertical field effect transistor includes forming a semiconductor nanowire that extends from a substrate surface. A first sacrificial layer is deposited over the substrate surface, and a second sacrificial layer is deposited over the first sacrificial layer such that each of the first and second sacrificial layers are formed peripheral to the nanowire. The second sacrificial layer is then patterned to form a dummy gate structure. Thereafter, the first sacrificial layer is removed and source and drain regions are deposited via epitaxy directly over respective portions of the nanowire.

Abstract: A method of forming a III-V semiconductor vertical fin is provided. The method includes forming a fin mandrel on a substrate, forming a spacer layer on the substrate surrounding the fin mandrel, forming a wetting layer on each of the sidewalls of the fin mandrel, forming a fin layer on each of the wetting layers, removing the fin mandrel, removing the wetting layer on each of the fin layers, and forming a fin layer regrowth on each of the sidewalls of the fin layers exposed by removing the wetting layer from each of the fin layers.

Abstract: A structure for use in a fin of a FinFET includes a hard mask formed on a substrate. The hard mask has an opening with at least a portion of the substrate exposed therein. The structure also includes a buffer formed on the portion of the substrate exposed within the hard mask, and multiple channels formed on the substrate proximate to respective sides of the opening.

Abstract: A method for manufacturing a semiconductor device includes forming a plurality of transistors on a semiconductor substrate. The formation of the plurality of transistors includes recessing channels of at least two transistors of the plurality of transistors. In the method, a stacked capacitor is formed on the semiconductor substrate, and the stacked capacitor is electrically connected in parallel to the at least two transistors of the plurality of transistors comprising the recessed channels and to an additional one of the plurality of transistors. The stacked capacitor, the at least two transistors and the additional one of the plurality of transistors form a memory cell of a plurality of memory cells of a memory device.

Abstract: A semiconductor device includes a stack of layers stacked vertically and including a source layer, a drain layer and a channel layer between the source layer and the drain layer. A gate electrode is formed in a common plane with the channel layer and a gate dielectric is formed vertically between the gate electrode and the channel layer. A first contact contacts the stack of layers on a first side of the stack of layers, and a second contact formed on an opposite side vertically from the first contact.

Abstract: Non-planar field effect transistor (FET) devices having wrap-around source/drain contacts are provided, as well as methods for fabricating non-planar FET devices with wrap-around source/drain contacts. A method includes forming a non-planar FET device on a substrate, which includes a semiconductor channel layer, and a gate structure in contact with upper and sidewall surfaces of the semiconductor channel layer. First and second source/drain regions are formed on opposite sides of the gate structure in contact with the semiconductor channel layer. First and second recesses are formed in an isolation layer below bottom surfaces of the first and second source/drain regions, respectively. A layer of metallic material is deposited to fill the first and second recesses in the isolation layer with metallic material and form first and second source/drain contacts which surround the first and second source/drain regions.

Abstract: A method of forming a self-forming spacer using oxidation. The self-forming spacer may include forming a fin field effect transistor on a substrate, the fin field effect transistor includes a gate on a fin, the gate is perpendicular to the fin; forming a gate spacer on the gate and a fin spacer on the fin, the gate spacer and the fin spacer are formed in a single step by oxidizing an exposed surface of the gate and an exposed surface of the fin; and removing the fin spacer from the fin.

Abstract: Semiconductor devices and methods are provided to fabricate field effect transistor (FET) devices having local wiring between the stacked devices. For example, a semiconductor device includes a first FET device on a semiconductor substrate, the FET device comprising a first source/drain layer, and a first gate structure comprising a gate dielectric layer and a metal gate layer. The semiconductor device further includes a second FET device comprising a second source/drain layer, and a second gate structure comprising a gate dielectric layer and a metal gate layer, wherein the first and second FET devices are in a stacked configuration. The semiconductor device further includes one or more conductive vias in communication with either the first gate structure of the first FET device or the second gate structure of the second FET device.

Abstract: Device and method for fabricating a field effect transistor (FET) include forming plurality of dummy dielectric layers separated by a corresponding plurality of source/drain regions overlying a substrate. One or more nanosheets of active transistor channels alternating between the plurality of dummy dielectric layers are formed extending at least part way into the plurality of source/drain regions. A high-k dielectric layer is formed about and overlying the source/drain regions and portions of the one or more nanosheets not covered by the plurality of dummy dielectric layers. A conductive metal cap layer is formed overlying the high-k dielectric layer.

Abstract: A method for fabricating caterpillar trenches for wafer dicing includes forming at least one opening within a mask formed on a substrate to protect an electronics device disposed on the substrate during isotropic etching, and isotropically etching through the at least one opening to form at least one wafer dicing channel, including laterally etching a collection of nested trenches including trenches each having a non-circular cross-section from a first surface of the substrate to a second surface of the substrate opposite the first surface.

Abstract: A method for doping fins includes, for a first dopant layer formed in a first region and a second region to a height continuously below a top portion of a plurality of fins such that an entirety of the first dopant layer is formed below the top portion of the plurality of fins, and a dielectric layer formed over the top portion of the plurality of fins, removing the dielectric layer and the first dopant layer in the first region to expose a first fin in the first region, forming a second dopant layer over the first fin, and annealing to drive dopants into the fins from the first dopant layer in the second region and from the second dopant layer in the first region.