Abstract: Methods of forming a memory device structure are described. Those methods may include forming a non-conductive spacer material on a top electrode of a magnetic tunnel junction structure, and then forming a highly selective material on the non-conductive spacer material of the magnetic tunnel junction prior to etching a bottom electrode of the magnetic tunnel junction.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a structure comprising a first contact metal disposed on a source/drain contact of a substrate, and a second contact metal disposed on a top surface of the first contact metal, wherein the second contact metal is disposed within an IID disposed on a top surface of a metal gate disposed on the substrate.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a structure comprising a first contact metal disposed on a source/drain contact of a substrate, and a second contact metal disposed on a top surface of the first contact metal, wherein the second contact metal is disposed within an IID disposed on a top surface of a metal gate disposed on the substrate.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a structure comprising a first contact metal disposed on a source/drain contact of a substrate, and a second contact metal disposed on a top surface of the first contact metal, wherein the second contact metal is disposed within an IID disposed on a top surface of a metal gate disposed on the substrate.

Abstract: A wrap-around source/drain trench contact structure is described. A plurality of semiconductor fins extend from a semiconductor substrate. A channel region is disposed in each fin between a pair of source/drain regions. An epitaxial semiconductor layer covers the top surface and sidewall surfaces of each fin over the source/drain regions, defining high aspect ratio gaps between adjacent fins. A pair of source/drain trench contacts are electrically coupled to the epitaxial semiconductor layers. The source/drain trench contacts comprise a conformal metal layer and a fill metal. The conformal metal layer conforms to the epitaxial semiconductor layers. The fill metal comprises a plug and a barrier layer, wherein the plug fills a contact trench formed above the fins and the conformal metal layer, and the barrier layer lines the plug to prevent interdiffusion of the conformal metal layer material and plug material.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a source/drain region in an NMOS portion of a substrate, wherein the source/drain region of the NMOS portion comprises at least one dislocation, and wherein a PMOS source/drain region in a PMOS portion of the substrate does not comprise a dislocation.

Abstract: Techniques are disclosed for realizing a two-dimensional target lithography feature/pattern by decomposing (splitting) it into multiple unidirectional target features that, when aggregated, substantially (e.g., fully) represent the original target feature without leaving an unrepresented remainder (e.g., a whole-number quantity of unidirectional target features). The unidirectional target features may he arbitrarily grouped such that, within a grouping, all unidirectional target features share a common target width value. Where multiple such groupings are provided, individual groupings may or may not have the same common target width value. In some cases, a series of reticles is provided, each reticle having a mask pattern correlating to a grouping of unidirectional target features. Exposure of a photoresist material via the aggregated series of reticles substantially (e.g., fully) produces the original target feature/pattern.

Abstract: Gate aligned contacts and methods of forming gate aligned contacts are described. For example, a method of fabricating a semiconductor structure includes forming a plurality of gate structures above an active region formed above a substrate. The gate structures each include a gate dielectric layer, a gate electrode, and sidewall spacers. A plurality of contact plugs is formed, each contact plug formed directly between the sidewall spacers of two adjacent gate structures of the plurality of gate structures. A plurality of contacts is formed, each contact formed directly between the sidewall spacers of two adjacent gate structures of the plurality of gate structures. The plurality of contacts and the plurality of gate structures are formed subsequent to forming the plurality of contact plugs.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a source/drain region in an NMOS portion of a substrate, wherein the source/drain region of the NMOS portion comprises at least one dislocation, and wherein a PMOS source/drain region in a PMOS portion of the substrate does not comprise a dislocation.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a source/drain region in an NMOS portion of a substrate, wherein the source/drain region of the NMOS portion comprises at least one dislocation, and wherein a PMOS source/drain region in a PMOS portion of the substrate does not comprise a dislocation.

Abstract: A transistor comprises a gate (110) comprising a gate electrode (111) and a gate dielectric (112), an electrically insulating cap (120, 720) over the gate, and a source/drain contact (130) adjacent to the gate. The electrically insulating cap prevents electrical contact between the gate and the source/drain contact. In one embodiment, the electrically insulating cap is formed in a trench (160, 660) that is self-aligned to the gate and that is created by the removal of a sacrificial cap using an aqueous solution comprising a carboxylic acid and a corrosion inhibitor.

Abstract: A transistor comprises a gate (110) comprising a gate electrode (111) and a gate dielectric (112), an electrically insulating cap (120, 720) over the gate, and a source/drain contact (130) adjacent to the gate. The electrically insulating cap prevents electrical contact between the gate and the source/drain contact. In one embodiment, the electrically insulating cap is formed in a trench (160, 660) that is self-aligned to the gate and that is created by the removal of a sacrificial cap using an aqueous solution comprising a carboxylic acid and a corrosion inhibitor.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming an NMOS silicide on an NMOS source/drain contact area, forming a first contact metal on the NMOS silicide, polishing the first contact metal to expose a top surface of a PMOS source/drain region, and forming a PMOS silicide on the PMOS source/drain region.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming an NMOS silicide on an NMOS source/drain contact area, forming a first contact metal on the NMOS silicide, polishing the first contact metal to expose a top surface of a PMOS source/drain region, and forming a PMOS silicide on the PMOS source/drain region.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a source/drain region in an NMOS portion of a substrate, wherein the source/drain region of the NMOS portion comprises at least one dislocation, and wherein a PMOS source/drain region in a PMOS portion of the substrate does not comprise a dislocation.

Abstract: Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a structure comprising a first contact metal disposed on a source/drain contact of a substrate, and a second contact metal disposed on a top surface of the first contact metal, wherein the second contact metal is disposed within an IID disposed on a top surface of a metal gate disposed on the substrate.

Abstract: In some embodiments an etchstop layer is deposited over a transistor that has been encapsulated by a high-K film, a silicon nitride is deposited over the deposited etchstop layer, the silicon nitride is removed, and the etchstop layer is removed. Other embodiments are described and claimed.

Abstract: A transistor comprises a gate (110) comprising a gate electrode (111) and a gate dielectric (112), an electrically insulating cap (120, 720) over the gate, and a source/drain contact (130) adjacent to the gate. The electrically insulating cap prevents electrical contact between the gate and the source/drain contact. In one embodiment, the electrically insulating cap is formed in a trench (160, 660) that is self-aligned to the gate and that is created by the removal of a sacrificial cap using an aqueous solution comprising a carboxylic acid and a corrosion inhibitor.

Abstract: The performance of NMOS and PMOS regions of integrated circuits is improved. Embodiments of the invention include forming a first dielectric layer optimized for n-doped regions over the n-doped regions and forming a second dielectric layer optimized for p-doped regions over p-doped regions.

Abstract: The performance of NMOS and PMOS regions of integrated circuits is improved. Embodiments of the invention include forming a first dielectric layer optimized for n-doped regions over the n-doped regions and forming a second dielectric layer optimized for p-doped regions over p-doped regions.