Abstract: One method disclosed herein includes forming a virtual substrate by forming a sacrificial semiconductor material in a trench between a plurality of silicon fin structures formed in a bulk silicon substrate, forming a layer of silicon above the silicon fin structures and the sacrificial semiconductor material, performing at least one etching process to selectively remove the sacrificial semiconductor material relative to the silicon fin structures and the layer of silicon so as to define a cavity, forming a non-sacrificial semiconductor material on the layer of silicon and forming a layer of strained channel semiconductor material above the non-sacrificial semiconductor material positioned above the upper surface of the layer of silicon.

Abstract: A method of forming a semiconductor structure includes forming a first isolation region between fins of a first group of fins and between fins of a second group of fins. The first a second group of fins are formed in a bulk semiconductor substrate. A second isolation region is formed between the first group of fins and the second group of fins, the second isolation region extends through a portion of the first isolation region such that the first and second isolation regions are in direct contact and a height above the bulk semiconductor substrate of the second isolation region is greater than a height above the bulk semiconductor substrate of the first isolation region.

Abstract: Disclosed are methods and devices that involve formation of alternating layers of different semiconductor materials in the channel region of FinFET devices. The methods and devices disclosed herein involve forming a doped silicon substrate fin and thereafter forming a layer of silicon/germanium around the substrate fin. The methods and devices also include forming a gate structure around the layer of silicon/germanium using gate first or gate last techniques.

Abstract: Embodiments herein provide approaches for device isolation in a complimentary metal-oxide fin field effect transistor. Specifically, a semiconductor device is formed with a retrograde doped layer over a substrate to minimize a source to drain punch-through leakage. A set of replacement fins is formed over the retrograde doped layer, each of the set of replacement fins comprising a high mobility channel material (e.g., silicon, or silicon-germanium). The retrograde doped layer may be formed using an in situ doping process or a counter dopant retrograde implant. The device may further include a carbon liner positioned between the retrograde doped layer and the set of replacement fins to prevent carrier spill-out to the replacement fins.

Abstract: One illustrative method disclosed herein includes, among other things, oxidizing a lower portion of an initial fin structure to thereby define an isolation region that vertically separates an upper portion of the initial fin structure from a semiconducting substrate, performing a recess etching process to remove a portion of the upper portion of the initial fin structure so as to define a recessed fin portion, forming a replacement fin on the recessed fin portion so as to define a final fin structure comprised of the replacement fin and the recessed fin portion, and forming a gate structure around at least a portion of the replacement fin.

Abstract: One illustrative method disclosed herein includes forming a recessed fin structure and a replacement fin cavity in a layer of insulating material above the recessed fin structure, forming at least first and second individual layers of epi semiconductor material in the replacement fin cavity, wherein each of the first and second layers have different concentrations of germanium, performing an anneal process on the first and second layers so as to form a substantially homogeneous SiGe replacement fin in the fin cavity, and forming a gate structure around at least a portion of the replacement fin.

Abstract: Embodiments herein provide device isolation in a complimentary metal-oxide fin field effect transistor. Specifically, a semiconductor device is formed with a retrograde doped layer over a substrate to minimize a source to drain punch-through leakage. A set of high mobility channel fins is formed over the retrograde doped layer, each of the set of high mobility channel fins comprising a high mobility channel material (e.g., silicon or silicon-germanium). The retrograde doped layer may be formed using an in situ doping process or a counter dopant retrograde implant. The device may further include a carbon liner positioned between the retrograde doped layer and the set of high mobility channel fins to prevent carrier spill-out to the high mobility channel fins.

Abstract: One illustrative method disclosed herein includes, among other things, forming a sacrificial fin structure above a semiconductor substrate, forming a layer of insulating material around the sacrificial fin structure, removing the sacrificial fin structure so as to define a replacement fin cavity in the layer of insulating material that exposes an upper surface of the substrate, forming a replacement fin in the replacement fin cavity on the exposed upper surface of the substrate, recessing the layer of insulating material, and forming a gate structure around at least a portion of the replacement fin exposed above the recessed layer of insulating material.

Abstract: A method of forming a FinFET device having Si or high Ge concentration SiGe fins with a narrow width under the gate and a wider width under the spacer and the resulting device are provided. Embodiments include forming fins; forming a dummy gate, with a dummy oxide thereunder and a nitride HM on top, on the fins, the dummy gate formed perpendicular to the fins; forming a nitride spacer on each side of the dummy gate; forming an oxide in-between adjacent gates and planarizing; removing the nitride HM and dummy gate, forming a channel between the nitride spacers; oxidizing the fins in the channel; removing the dummy oxide and oxidized portions of the fins; and forming a RMG on the fins between the nitride spacers.

Abstract: One illustrative method disclosed herein includes, among other things, performing an epitaxial deposition process to form an epi SiGe layer above a recessed layer of insulating material and on an exposed portion of a fin, wherein the concentration of germanium in the layer of epi silicon-germanium (SixGe1-x) is equal to or greater than a target concentration of germanium for the final fin, performing a thermal anneal process in an inert processing environment to cause germanium in the epi SiGe to diffuse into the fin and thereby define an SiGe region in the fin, after performing the thermal anneal process, performing at least one process operation to remove the epi SiGe and, after removing the epi SiGe, forming a gate structure around at least a portion of the SiGe region.

Abstract: One illustrative device disclosed herein includes a substrate fin formed in a substrate comprised of a first semiconductor material, wherein at least a sidewall of the substrate fin is positioned substantially in a <100> crystallographic direction of the crystalline structure of the substrate, a replacement fin structure positioned above the substrate fin, wherein the replacement fin structure is comprised of a semiconductor material that is different from the first semiconductor material, and a gate structure positioned around at least a portion of the replacement fin structure.

Abstract: A FinFET has a structure including a semiconductor substrate, semiconductor fins and a gate spanning the fins. The fins each have a bottom region coupled to the substrate and a top active region. Between the bottom and top fin regions is a middle stack situated between a vertically elongated source and a vertically elongated drain. The stack includes a top channel region and a dielectric region immediately below the channel region, providing electrical isolation of the channel. The partial isolation structure can be used with both gate first and gate last fabrication processes.

Abstract: A method of forming a semiconductor structure includes forming a first isolation region between fins of a first group of fins and between fins of a second group of fins. The first a second group of fins are formed in a bulk semiconductor substrate. A second isolation region is formed between the first group of fins and the second group of fins, the second isolation region extends through a portion of the first isolation region such that the first and second isolation regions are in direct contact and a height above the bulk semiconductor substrate of the second isolation region is greater than a height above the bulk semiconductor substrate of the first isolation region.

Abstract: Embodiments herein provide device isolation in a complimentary metal-oxide fin field effect transistor. Specifically, a semiconductor device is formed with a retrograde doped layer over a substrate to minimize a source to drain punch-through leakage. A set of high mobility channel fins is formed over the retrograde doped layer, each of the set of high mobility channel fins comprising a high mobility channel material (e.g., silicon or silicon-germanium). The retrograde doped layer may be formed using an in situ doping process or a counter dopant retrograde implant. The device may further include a carbon liner positioned between the retrograde doped layer and the set of high mobility channel fins to prevent carrier spill-out to the high mobility channel fins.

Abstract: Fin field effect transistor integrated circuits and methods for producing the same are provided. A fin field effect transistor integrated circuit includes a plurality of fins extending from a semiconductor substrate. Each of the plurality of fins includes a fin sidewall, and each of the plurality of fins extends to a fin height such that a trough with a trough base is defined between adjacent fins. A second dielectric is positioned within the trough, where the second dielectric directly contacts the semiconductor substrate at the trough base. The second dielectric extends to a second dielectric height less than the fin height such that protruding fin portions extend above the second dielectric. A first dielectric is positioned between the fin sidewall and the second dielectric.

Abstract: One illustrative method disclosed herein includes, among other things, forming a fin in a semiconductor substrate and performing an epitaxial deposition process using a combination of silane (SiH4), dichlorosilane (SiH2Cl2), germane (GeH4) and a carrier gas to form an epi semiconductor material around the fin, wherein the flow rate of dichlorosilane used during the epitaxial deposition process is equal to 10-90% of the combined flow rate of silane and dichlorosilane.

Abstract: Methods of forming a defect free heteroepitaxial replacement fin by annealing the sacrificial Si fin with H2 prior to STI formation are provided. Embodiments include forming a Si fin on a substrate; annealing the Si fin with H2; forming a STI layer around the annealed Si fin; annealing the STI layer; removing a portion of the annealed Si fin by etching, forming a recess; forming a replacement fin in the recess; and recessing the annealed STI layer to expose an active replacement fin.

Abstract: One illustrative method disclosed herein includes, among other things, performing an epitaxial deposition process to form an epi SiGe layer above a recessed layer of insulating material and on an exposed portion of a fin, wherein the concentration of germanium in the layer of epi silicon-germanium (SixGe1-x) is equal to or greater than a target concentration of germanium for the final fin, performing a thermal anneal process in an inert processing environment to cause germanium in the epi SiGe to diffuse into the fin and thereby define an SiGe region in the fin, after performing the thermal anneal process, performing at least one process operation to remove the epi SiGe and, after removing the epi SiGe, forming a gate structure around at least a portion of the SiGe region.

Abstract: One illustrative method disclosed herein includes, among other things, oxidizing a lower portion of an initial fin structure to thereby define an isolation region that vertically separates an upper portion of the initial fin structure from a semiconducting substrate, performing a recess etching process to remove a portion of the upper portion of the initial fin structure so as to define a recessed fin portion, forming a replacement fin on the recessed fin portion so as to define a final fin structure comprised of the replacement fin and the recessed fin portion, and forming a gate structure around at least a portion of the replacement fin.

Abstract: Forming a plurality of initial trenches that extend through a layer of silicon-germanium and into a substrate to define an initial fin structure comprised of a portion of the layer of germanium-containing material and a first portion of the substrate, forming sidewall spacers adjacent the initial fin structure, performing an etching process to extend the initial depth of the initial trenches, thereby forming a plurality of final trenches having a final depth that is greater than the initial depth and defining a second portion of the substrate positioned under the first portion of the substrate, forming a layer of insulating material over-filling the final trenches and performing a thermal anneal process to convert at least a portion of the first or second portions of the substrate into a silicon dioxide isolation material that extends laterally under an entire width of the portion of the germanium-containing material.