Abstract: A semiconductor device includes a substrate and a buffer layer disposed on a first portion, a second portion, and a third portion of the substrate. The semiconductor device further includes a multilayer light-emitting diode (LED) stack disposed on the first portion of the substrate, and an optical sensor disposed on the second portion of the substrate. The semiconductor device further includes at least one electrode disposed on the third portion of the substrate, a first conductor in contact with the multilayer LED stack, and a second conductor in contact with the optical sensor. The at least one electrode, the first conductor, and the second conductor are formed of a glassy carbon material.

Abstract: A semiconductor device includes a substrate and a buffer layer disposed on a first portion, a second portion, and a third portion of the substrate. The semiconductor device further includes a multilayer light-emitting diode (LED) stack disposed on the first portion of the substrate, and an optical sensor disposed on the second portion of the substrate. The semiconductor device further includes at least one electrode disposed on the third portion of the substrate, a first conductor in contact with the multilayer LED stack, and a second conductor in contact with the optical sensor. The at least one electrode, the first conductor, and the second conductor are formed of a glassy carbon material.

Abstract: A semiconductor device includes a substrate and a buffer layer disposed on a first portion, a second portion, and a third portion of the substrate. The semiconductor device further includes a multilayer light-emitting diode (LED) stack disposed on the first portion of the substrate, and an optical sensor disposed on the second portion of the substrate. The semiconductor device further includes at least one electrode disposed on the third portion of the substrate, a first conductor in contact with the multilayer LED stack, and a second conductor in contact with the optical sensor. The at least one electrode, the first conductor, and the second conductor are formed of a glassy carbon material.

Abstract: A semiconductor device includes a substrate and a buffer layer disposed on a first portion, a second portion, and a third portion of the substrate. The semiconductor device further includes a multilayer light-emitting diode (LED) stack disposed on the first portion of the substrate, and an optical sensor disposed on the second portion of the substrate. The semiconductor device further includes at least one electrode disposed on the third portion of the substrate, a first conductor in contact with the multilayer LED stack, and a second conductor in contact with the optical sensor. The at least one electrode, the first conductor, and the second conductor are formed of a glassy carbon material.

Abstract: An improved transistor with channel epitaxial silicon. In one aspect, a method of fabrication includes: forming a gate stack structure on an epitaxial silicon region disposed on a substrate, a width dimension of the epitaxial silicon region approximating a width dimension of the gate stack structure; and growing a raised epitaxial source and drain from the substrate, the raised epitaxial source and drain in contact with the epitaxial silicon region and the gate stack structure. For a SRAM device, further: removing an epitaxial layer in contact with the silicon substrate and the raised source and drain and to which the epitaxial silicon region is coupled leaving a space above the silicon substrate and under the raised epitaxial source and drain; and filling the space with an insulating layer and isolating the raised epitaxial source and drain and a channel of the transistor from the silicon substrate.

Abstract: A method of making a structurally stable SiGe-on-insulator FinFET employs a silicon nitride liner to prevent de-stabilizing oxidation at the base of a SiGe fin. The silicon nitride liner blocks access of oxygen to the lower corners of the fin to facilitate fabrication of a high-concentration SiGe fin. The silicon nitride liner is effective as an oxide barrier even if its thickness is less than about 5 nm. Use of the SiN liner provides structural stability for fins that have higher germanium content, in the range of 25-55% germanium concentration.

Abstract: A fin of silicon-germanium material is formed and covered with an epitaxially grown layer of silicon material. A dummy transistor gate is then formed to extend over a channel of the fin. Sidewall spacers are formed on each side of the dummy transistor gate and directly on top of the expitaxial silicon layer. Epitaxially grown raised source and drain regions are formed on each side of the dummy transistor gate adjacent the sidewall spacers. The dummy transistor gate and a portion of the epitaxial silicon layer (underneath said dummy transistor gate) are removed and replaced by a metal gate.

Abstract: An improved transistor with channel epitaxial silicon and methods for fabrication thereof. In one aspect, a method for fabricating a transistor includes: forming a gate stack structure on an epitaxial silicon region, a width dimension of the epitaxial silicon region approximating a width dimension of the gate stack structure; encapsulating the epitaxial silicon region under the gate stack structure with sacrificial spacers formed on both sides of the gate stack structure and the epitaxial silicon region; forming a channel of the transistor having a width dimension that approximates that of the epitaxial silicon region and the gate stack structure, the epitaxial silicon region and the gate stack structure formed on the channel of the transistor; removing the sacrificial spacers; and growing a raised epitaxial source and drain from the silicon substrate, with portions of the raised epitaxial source and drain in contact with the epitaxial silicon region.

Abstract: A method of making a structurally stable SiGe-on-insulator FinFET employs a silicon nitride liner to prevent de-stabilizing oxidation at the base of a SiGe fin. The silicon nitride liner blocks access of oxygen to the lower corners of the fin to facilitate fabrication of a high-concentration SiGe fin. The silicon nitride liner is effective as an oxide barrier even if its thickness is less than about 5 nm. Use of the SiN liner provides structural stability for fins that have higher germanium content, in the range of 25-55% germanium concentration.

Abstract: A method of making a structurally stable SiGe-on-insulator FinFET employs a silicon nitride liner to prevent de-stabilizing oxidation at the base of a SiGe fin. The silicon nitride liner blocks access of oxygen to the lower corners of the fin to facilitate fabrication of a high-concentration SiGe fin. The silicon nitride liner is effective as an oxide barrier even if its thickness is less than about 5 nm. Use of the SiN liner provides structural stability for fins that have higher germanium content, in the range of 25-55% germanium concentration.

Abstract: A method of preventing corner rounding for an alternate channel FINFET formed in trenches and the resulting devices are provided. Embodiments include providing a Si substrate; forming a trench in the Si substrate; forming a Si based layer with a flat upper surface in the trench; and forming a SiGe layer over the Si based layer.

Abstract: An electronic device may include a substrate, a buried oxide (BOX) layer overlying the substrate, at least one semiconductor device overlying the BOX layer, and at least one shallow trench isolation (STI) region in the substrate and adjacent the at least one semiconductor device. The at least one STI region defines a sidewall surface with the substrate and may include an oxide layer lining a bottom portion of the sidewall surface, a nitride layer lining a top portion of the sidewall surface above the bottom portion, and an insulating material within the nitride and oxide layers.

Abstract: An improved transistor with channel epitaxial silicon. In one aspect, a method of fabrication includes: forming a gate stack structure on an epitaxial silicon region disposed on a substrate, a width dimension of the epitaxial silicon region approximating a width dimension of the gate stack structure; and growing a raised epitaxial source and drain from the substrate, the raised epitaxial source and drain in contact with the epitaxial silicon region and the gate stack structure. For a SRAM device, further: removing an epitaxial layer in contact with the silicon substrate and the raised source and drain and to which the epitaxial silicon region is coupled leaving a space above the silicon substrate and under the raised epitaxial source and drain; and filling the space with an insulating layer and isolating the raised epitaxial source and drain and a channel of the transistor from the silicon substrate.

Abstract: An improved transistor with channel epitaxial silicon and methods for fabrication thereof. In one aspect, a method for fabricating a transistor includes: forming a gate stack structure on an epitaxial silicon region, a width dimension of the epitaxial silicon region approximating a width dimension of the gate stack structure; encapsulating the epitaxial silicon region under the gate stack structure with sacrificial spacers formed on both sides of the gate stack structure and the epitaxial silicon region; forming a channel of the transistor having a width dimension that approximates that of the epitaxial silicon region and the gate stack structure, the epitaxial silicon region and the gate stack structure formed on the channel of the transistor; removing the sacrificial spacers; and growing a raised epitaxial source and drain from the silicon substrate, with portions of the raised epitaxial source and drain in contact with the epitaxial silicon region.

Abstract: Methods and semiconductor structures formed from the methods are provided which facilitate fabricating semiconductor fin structures. The methods include, for example: providing a wafer with at least one semiconductor fin extending above a substrate; transforming a portion of the semiconductor fin(s) into an isolation layer, the isolation layer separating a semiconductor layer of the semiconductor fin(s) from the substrate; and proceeding with forming a fin device(s) of a first architectural type in a first fin region of the semiconductor fin(s), and a fin device(s) of a second architectural type in a second fin region of the semiconductor fin(s), where the first architectural type and the second architectural type are different fin device architectures.

Abstract: One illustrative method disclosed herein includes, among other things, forming a fin in a semiconductor substrate, the fin having a lower first section that contains an oxidation-retarding implant region and an upper second section that is substantially free of the oxidation-retarding implant region, forming a sidewall spacer on opposite sides of the upper portion of the fin, forming a first layer of insulating material adjacent the sidewall spacers and the upper second section of the lower portion of the fin, and, with the first layer of insulating material in position, performing a thermal anneal process to convert the portion of the upper second section of the fin that is in contact with the first layer of insulating material into an oxide fin isolation region positioned under the fin above the lower first section of the fin.

Abstract: One illustrative method disclosed herein involves, among other things, forming trenches to form an initial fin structure having an initial exposed height and sidewalls, forming a protection layer on at least the sidewalls of the initial fin structure, extending the depth of the trenches to thereby define an increased-height fin structure, with a layer of insulating material over-filling the final trenches and with the protection layer in position, performing a fin oxidation thermal anneal process to convert at least a portion of the increased-height fin structure into an isolation material, removing the protection layer, and performing an epitaxial deposition process to form a layer of semiconductor material on at least portions of the initial fin structure.

Abstract: An improved transistor with channel epitaxial silicon and methods for fabrication thereof. In one aspect, a method for fabricating a transistor includes: forming a gate stack structure on an epitaxial silicon region, a width dimension of the epitaxial silicon region approximating a width dimension of the gate stack structure; encapsulating the epitaxial silicon region under the gate stack structure with sacrificial spacers formed on both sides of the gate stack structure and the epitaxial silicon region; forming a channel of the transistor having a width dimension that approximates that of the epitaxial silicon region and the gate stack structure, the epitaxial silicon region and the gate stack structure formed on the channel of the transistor; removing the sacrificial spacers; and growing a raised epitaxial source and drain from the silicon substrate, with portions of the raised epitaxial source and drain in contact with the epitaxial silicon region.

Abstract: An improved transistor with channel epitaxial silicon. In one aspect, a method of fabrication includes: forming a gate stack structure on an epitaxial silicon region disposed on a substrate, a width dimension of the epitaxial silicon region approximating a width dimension of the gate stack structure; and growing a raised epitaxial source and drain from the substrate, the raised epitaxial source and drain in contact with the epitaxial silicon region and the gate stack structure. For a SRAM device, further: removing an epitaxial layer in contact with the silicon substrate and the raised source and drain and to which the epitaxial silicon region is coupled leaving a space above the silicon substrate and under the raised epitaxial source and drain; and filling the space with an insulating layer and isolating the raised epitaxial source and drain and a channel of the transistor from the silicon substrate.

Abstract: An integrated circuit, including: a UTBOX layer; a first cell, including: FDSOI transistors; a first STI separating the transistors; a first ground plane located beneath one of the transistors and beneath the UTBOX layer; a first well; a second cell, including: FDSOI transistors; a second STI separating the transistors; a second ground plane located beneath one of the transistors and beneath the UTBOX layer; a second well; a third STI separating the cells, reaching the bottom of the first and second wells; a deep well extending continuously beneath the first and second wells, having a portion beneath the third STI whose doping density is at least 50% higher than the doping density of the deep well beneath the first and second STIs.