A method for manufacturing a semiconductor device comprises epitaxially growing a plurality of silicon layers and compressively strained silicon germanium (SiGe) layers on a substrate in a stacked configuration, wherein the silicon layers and compressively strained SiGe layers are alternately stacked on each other starting with a silicon layer on a bottom of the stacked configuration, patterning the stacked configuration to a first width, selectively removing a portion of each of the silicon layers in the stacked configuration to reduce the silicon layers to a second width less than the first width, forming an oxide layer on the compressively strained SiGe layers of the stacked configuration, wherein forming the oxide layer comprises fully oxidizing the silicon layers so that portions of the oxide layer are formed in place of each fully oxidized silicon layer, and removing part of the oxide layer while maintaining at least part of the portions of the oxide layer formed in place of each fully oxidized silicon layer, wherein the compressively strained SiGe layers are anchored to one another and a compressive strain is maintained in each of the compressively strained SiGe layers.

Described herein is a FinFET device in which epitaxial layers of semiconductor material are formed in the source/drain regions on dielectrically isolated fin portions. The fin portions are located within a dielectric layer that is deposited on a semiconductor substrate. Surfaces of the fin portions are oriented in the {100} lattice plane of the crystalline material of the fin portions, providing for good epitaxial growth. Further described are methods for forming the FinFET device.

Semiconductor devices having necked semiconductor bodies and methods of forming semiconductor bodies of varying width are described. For example, a semiconductor device includes a semiconductor body disposed above a substrate. A gate electrode stack is disposed over a portion of the semiconductor body to define a channel region in the semiconductor body under the gate electrode stack. Source and drain regions are defined in the semiconductor body on either side of the gate electrode stack. Sidewall spacers are disposed adjacent to the gate electrode stack and over only a portion of the source and drain regions. The portion of the source and drain regions under the sidewall spacers has a height and a width greater than a height and a width of the channel region of the semiconductor body.

Techniques are disclosed for enabling multi-sided condensation of semiconductor fins The techniques can be employed, for instance, in fabricating fin-based transistors. In one example case, a strain layer is provided on a bulk substrate. The strain layer is associated with a critical thickness that is dependent on a component of the strain layer, and the strain layer has a thickness lower than or equal to the critical thickness. A fin is formed in the substrate and strain layer, such that the fin includes a substrate portion and a strain layer portion. The fin is oxidized to condense the strain layer portion of the fin, so that a concentration of the component in the strain layer changes from a pre-condensation concentration to a higher post-condensation concentration, thereby causing the critical thickness to be exceeded.

Embodiments are directed to forming a structure comprising at least one fin, a gate, and a spacer, applying an annealing process to the structure to create a gap between the at least one fin and the spacer, and growing an epitaxial semiconductor layer in the gap between the spacer and the at least one fin.

One method includes forming a plurality of first trenches in a semiconductor substrate to thereby define a plurality of initial fins in the substrate, removing at least one, but less than all, of the plurality of initial fins, forming a fin protection layer on at least the sidewalls of the remaining initial fins, with the fin protection layer in position, performing an etching process to extend a depth of the first trenches to thereby define a plurality of final trenches with a final trench depth, wherein the final trenches define a plurality of final fin structures that each comprise an initial fin, removing the fin protection layer, and forming a recessed layer of insulating material in the final trenches, wherein the recessed layer of insulating material has a recessed surface that exposes a portion of the final fin structures.

In one aspect, a method of forming finFET devices is provided which includes patterning fins in a wafer; forming dummy gates over the fins; forming spacers on opposite sides of the dummy gates; depositing a gap fill oxide on the wafer, filling any gaps between the spacers; removing the dummy gates forming gate trenches; trimming the fins within the gate trenches such that a width of the fins within the gate trenches is less than the width of the fins under the spacers adjacent to the gate trenches, wherein u-shaped grooves are formed in sides of the fins within the gate trenches; and forming replacement gate stacks in the gate trenches, wherein portions of the fins adjacent to the replacement gate stacks serve as source and drain regions of the finFET devices.

A threshold voltage tuning approach for forming a stacked nanowire gate-all around pFET is provided. In the present application, selective condensation (i.e., oxidation) is used to provide a threshold voltage shift in silicon germanium alloy nanowires. The threshold voltage shift is well controlled because both underlying parameters which govern the final germanium content, i.e., nanowire width and amount of condensation, are well controlled by the selective condensation process. The present application can address the problem of width quantization in stacked nanowire FETs by offering various device options.

A method for forming strained fins includes etching trenches in a bulk substrate to form fins, filling the trenches with a dielectric fill and recessing the dielectric fill into the trenches to form shallow trench isolation regions. The fins are etched above the shallow trench isolation regions to form a staircase fin structure with narrow top portions of the fins. Gate structures are formed over the top portions of the fins. Raised source ad drain regions are epitaxially grown on opposite sides of the gate structure. A pre-morphization implant is performed to generate defects in the substrate to couple strain into the top portions of the fins.

A method includes providing a substrate having a mesa, forming a first opening in the mesa, the first opening being surrounded by first inner sidewalls of the mesa exposed by the first opening. The method further includes etching from a first one of the first inner sidewalls of the mesa to form a first vertical recess, the first vertical recess having a wide end and a narrow end, with the narrow end defining a first vertically recessed channel region, and forming a first gate structure over the first vertically recessed channel region.