Abstract: Techniques are disclosed for forming transistors employing non-selective deposition of source and drain (S/D) material. Non-selectively depositing S/D material provides a multitude of benefits over only selectively depositing the S/D material, such as being able to attain relatively higher dopant activation, steeper dopant profiles, and better channel strain, for example.

Abstract: Semiconductor nanowire devices having cavity spacers and methods of fabricating cavity spacers for semiconductor nanowire devices are described. For example, a semiconductor device includes a plurality of vertically stacked nanowires disposed above a substrate, each of the nanowires including a discrete channel region. A common gate electrode stack surrounds each of the discrete channel regions of the plurality of vertically stacked nanowires. A pair of dielectric spacers is on either side of the common gate electrode stack, each of the pair of dielectric spacers including a continuous material disposed along a sidewall of the common gate electrode and surrounding a discrete portion of each of the vertically stacked nanowires. A pair of source and drain regions is on either side of the pair of dielectric spacers.

Abstract: Self-aligned gate edge trigate and finFET devices and methods of fabricating self-aligned gate edge trigate and finFET devices are described. In an example, a semiconductor structure includes a plurality of semiconductor fins disposed above a substrate and protruding through an uppermost surface of a trench isolation region. A gate structure is disposed over the plurality of semiconductor fins. The gate structure defines a channel region in each of the plurality of semiconductor fins. Source and drain regions are on opposing ends of the channel regions of each of the plurality of semiconductor fins, at opposing sides of the gate structure. The semiconductor structure also includes a plurality of gate edge isolation structures. Individual ones of the plurality of gate edge isolation structures alternate with individual ones of the plurality of semiconductor fins.

Abstract: Described herein are memory arrays where some memory cells include access transistors with one front-side and one back-side source/drain (S/D) contacts. An example memory array further includes a bitline, coupled to the first S/D region of the access transistor of a first memory cell of the memory array, and a plateline, coupled to a first capacitor electrode of a storage capacitor of the first memory cell. Because the access transistor is a transistor with one front-side and one back-side S/D contacts, the bitline may be provided in a first layer, the channel material—in a second layer, and the plateline—in a third layer, where the second layer is between the first layer and the third layer, which may allow increasing the density of memory cells in a memory array, or, conversely, reducing the footprint area of a memory array with a given density of memory cells.

Abstract: Described herein are memory arrays where some memory cells include access transistors with one front-side and one back-side source/drain (S/D) contacts. An example memory array further includes a bitline, coupled to the first S/D region of the access transistor of a first memory cell of the memory array, and a plateline, coupled to a first capacitor electrode of a storage capacitor of the first memory cell. Because the access transistor is a transistor with one front-side and one back-side S/D contacts, the bitline may be provided in a first layer, the channel material—in a second layer, and the plateline—in a third layer, where the second layer is between the first layer and the third layer, which may allow increasing the density of memory cells in a memory array, or, conversely, reducing the footprint area of a memory array with a given density of memory cells.

Abstract: Self-aligned gate edge trigate and finFET devices and methods of fabricating self-aligned gate edge trigate and finFET devices are described. In an example, a semiconductor structure includes a plurality of semiconductor fins disposed above a substrate and protruding through an uppermost surface of a trench isolation region. A gate structure is disposed over the plurality of semiconductor fins. The gate structure defines a channel region in each of the plurality of semiconductor fins. Source and drain regions are on opposing ends of the channel regions of each of the plurality of semiconductor fins, at opposing sides of the gate structure. The semiconductor structure also includes a plurality of gate edge isolation structures. Individual ones of the plurality of gate edge isolation structures alternate with individual ones of the plurality of semiconductor fins.

Abstract: Integrated circuit cell architectures including both front-side and back-side structures. One or more of back-side implant, semiconductor deposition, dielectric deposition, metallization, film patterning, and wafer-level layer transfer is integrated with front-side processing. Such double-side processing may entail revealing a back side of structures fabricated from the front-side of a substrate. Host-donor substrate assemblies may be built-up to support and protect front-side structures during back-side processing. Front-side devices, such as FETs, may be modified and/or interconnected during back-side processing. Electrical test may be performed from front and back sides of a workpiece. Back-side devices, such as FETs, may be integrated with front-side devices to expand device functionality, improve performance, or increase device density.

Abstract: Fin shaping, and integrated circuit structures resulting therefrom, are described. For example, an integrated circuit structure includes a semiconductor fin having a protruding fin portion above an isolation structure above a substrate. The protruding fin portion has substantially vertical upper sidewalls and outwardly tapered lower sidewalls. A gate stack is over and conformal with the protruding fin portion of the semiconductor fin. A first source or drain region is at a first side of the gate stack, and a second source or drain region is at a second side of the gate stack opposite the first side of the gate stack.

Abstract: Techniques are disclosed for forming increasing channel region tensile strain in n-MOS devices. In some cases, increased channel region tensile strain can be achieved via S/D material engineering that deliberately introduces dislocations in one or both of the S/D regions to produce tensile strain in the adjacent channel region. In some such cases, the S/D material engineering to create desired dislocations may include using a lattice mismatched epitaxial S/D film adjacent to the channel region. Numerous material schemes for achieving multiple dislocations in one or both S/D regions will be apparent in light of this disclosure. In some cases, a cap layer can be formed on an S/D region to reduce contact resistance, such that the cap layer is an intervening layer between the S/D region and S/D contact. The cap layer includes different material than the underlying S/D region and/or a higher dopant concentration to reduce contact resistance.

Abstract: Techniques related to forming selective gate spacers for semiconductor devices and transistor structures and devices formed using such techniques are discussed. Such techniques include forming a blocking material on a semiconductor fin, disposing a gate having a different surface chemistry than the blocking material on a portion of the blocking material, forming a selective conformal layer on the gate but not on a portion of the blocking material, and removing exposed portions of the blocking material.

Abstract: Methods of selectively nitriding surfaces of semiconductor devices are disclosed. For example, a hardmask is formed on the top portion of the fins to create SOI structure. The hardmask may be formed by nitriding the top portion of the fin. In other embodiments, silicon nitride is grown on the top portion of the fin to form the hard masks. In another example, internal spacers are formed between adjacent nanowires in a gate-all-around structure. The internal spacers may be formed by nitriding the remaining interlayer material between the channel region and source and drain regions.

Abstract: Techniques related to forming selective gate spacers for semiconductor devices and transistor structures and devices formed using such techniques are discussed. Such techniques include forming a blocking material on a semiconductor fin, disposing a gate having a different surface chemistry than the blocking material on a portion of the blocking material, forming a selective conformal layer on the gate but not on a portion of the blocking material, and removing exposed portions of the blocking material.

Abstract: Self-aligned gate endcap (SAGE) architectures without fin end gaps, and methods of fabricating self-aligned gate endcap (SAGE) architectures without fin end gaps, are described. In an example, an integrated circuit structure includes a semiconductor fin having a cut along a length of the semiconductor fin. A gate endcap isolation structure has a first portion parallel with the length of the semiconductor fin and is spaced apart from the semiconductor fin. The gate endcap isolation structure also has a second portion in a location of the cut of the semiconductor fin and in contact with the semiconductor fin.

Abstract: Solid assemblies having a composite dielectric spacer and processes for fabricating the solid assemblies are provided. The composite dielectric spacer can include, in some embodiments, a first dielectric layer and a second dielectric layer having a mutual interface. The composite dielectric spacer can separate a contact member from a conductive interconnect member, thus reducing the capacitance between such members with respect to solid assemblies that include one of first dielectric layer or the second dielectric layer. The composite dielectric spacer can permit maintaining the real estate of an interface between the conductive interconnect and a trench contact member that has an interface with a carrier-doped epitaxial layer embodying or constituting a source contact region or a drain contact region of a field effect transistor. The trench contact member can form another interface with the conductive interconnect member, providing a satisfactory contact resistance therebetween.

Abstract: Semiconductor contact architectures are provided, wherein contact metal extends into the semiconductor layer to which contact is being made, thereby increasing contact area. An offset spacer allows a relatively deep etch into the semiconductor material to be achieved. Thus, rather than just a flat horizontal surface of the semiconductor being exposed for contact area, relatively long vertical trench sidewalls and a bottom wall are exposed and available for contact area. The trench can then be filled with the desired contact metal. Doping of the semiconductor layer into which the contact is being formed can be carried out in a manner that facilitates an efficient contact trench etch process, such as by, for example, utilization of post trench etch doping or a semiconductor layer having an upper undoped region through which the contact trench etch passes and a lower doped S/D region. The offset spacer may be removed from final structure.

Abstract: Solid assemblies having a composite dielectric spacer and processes for fabricating the solid assemblies are provided. The composite dielectric spacer can include, in some embodiments, a first dielectric layer and a second dielectric layer having a mutual interface. The composite dielectric spacer can separate a contact member from a conductive interconnect member, thus reducing the capacitance between such members with respect to solid assemblies that include one of first dielectric layer or the second dielectric layer. The composite dielectric spacer can permit maintaining the real estate of an interface between the conductive interconnect and a trench contact member that has an interface with a carrier-doped epitaxial layer embodying or constituting a source contact region or a drain contact region of a field effect transistor. The trench contact member can form another interface with the conductive interconnect member, providing a satisfactory contact resistance therebetween.

Abstract: Self-aligned gate edge and local interconnect structures and methods of fabricating self-aligned gate edge and local interconnect structures are described. In an example, a semiconductor structure includes a semiconductor fin disposed above a substrate and having a length in a first direction. A gate structure is disposed over the semiconductor fin, the gate structure having a first end opposite a second end in a second direction, orthogonal to the first direction. A pair of gate edge isolation structures is centered with the semiconductor fin. A first of the pair of gate edge isolation structures is disposed directly adjacent to the first end of the gate structure, and a second of the pair of gate edge isolation structures is disposed directly adjacent to the second end of the gate structure.

Abstract: Self-aligned gate edge and local interconnect structures and methods of fabricating self-aligned gate edge and local interconnect structures are described. In an example, a semiconductor structure includes a semiconductor fin disposed above a substrate and having a length in a first direction. A gate structure is disposed over the semiconductor fin, the gate structure having a first end opposite a second end in a second direction, orthogonal to the first direction. A pair of gate edge isolation structures is centered with the semiconductor fin. A first of the pair of gate edge isolation structures is disposed directly adjacent to the first end of the gate structure, and a second of the pair of gate edge isolation structures is disposed directly adjacent to the second end of the gate structure.

Abstract: Methods of selectively nitriding surfaces of semiconductor devices are disclosed. For example, a hardmask is formed on the top portion of the fins to create SOI structure. The hardmask may be formed by nitriding the top portion of the fin. In other embodiments, silicon nitride is grown on the top portion of the fin to form the hard masks. In another example, internal spacers are formed between adjacent nanowires in a gate-all-around structure. The internal spacers may be formed by nitriding the remaining interlayer material between the channel region and source and drain regions.

Abstract: Techniques are disclosed for forming nanowire transistor architectures in which the presence of gate material between neighboring nanowires is eliminated or otherwise reduced. In some examples, neighboring nanowires can be formed sufficiently proximate one another such that their respective gate dielectric layers are either: (1) just in contact with one another (e.g., are contiguous); or (2) merged with one another to provide a single, continuous dielectric layer shared by the neighboring nanowires. In some cases, a given gate dielectric layer may be of a multi-layer configuration, having two or more constituent dielectric layers. Thus, in some examples, the gate dielectric layers of neighboring nanowires may be formed such that one or more constituent dielectric layers are either: (1) just in contact with one another (e.g., are contiguous); or (2) merged with one another to provide a single, continuous constituent dielectric layer shared by the neighboring nanowires.