Abstract: Examples herein relate to a memory device comprising an eDRAM memory cell, the eDRAM memory cell can include a write circuit formed at least partially over a storage cell and a read circuit formed at least partially under the storage cell; a compute near memory device bonded to the memory device; a processor; and an interface from the memory device to the processor. In some examples, circuitry is included to provide an output of the memory device to emulate output read rate of an SRAM memory device comprises one or more of: a controller, a multiplexer, or a register. Bonding of a surface of the memory device can be made to a compute near memory device or other circuitry. In some examples, a layer with read circuitry can be bonded to a layer with storage cells. Any layers can be bonded together using techniques described herein.

Abstract: IC interconnect structures including subtractively patterned features. Feature ends may be defined through multiple patterning of multiple cap materials for reduced misregistration. Subtractively patterned features may be lines integrated with damascene vias or with subtractively patterned vias, or may be vias integrated with damascene lines or with subtractively patterned lines. Subtractively patterned vias may be deposited as part of a planar metal layer and defined currently with interconnect lines. Subtractively patterned features may be integrated with air gap isolation structures. Subtractively patterned features may be include a barrier material on the bottom, top, or sidewall. A bottom barrier of a subtractively patterned features may be deposited with an area selective technique to be absent from an underlying interconnect feature. A barrier of a subtractively patterned feature may comprise graphene or a chalcogenide of a metal in the feature or in a seed layer.

Abstract: Conformal hermetic dielectric films suitable as dielectric diffusion barriers over 3D topography. In embodiments, the dielectric diffusion barrier includes a dielectric layer, such as a metal oxide, which can be deposited by atomic layer deposition (ALD) techniques with a conformality and density greater than can be achieved in a conventional silicon dioxide-based film deposited by a PECVD process for a thinner contiguous hermetic diffusion barrier. In further embodiments, the diffusion barrier is a multi-layered film including a high-k dielectric layer and a low-k or intermediate-k dielectric layer (e.g., a bi-layer) to reduce the dielectric constant of the diffusion barrier. In other embodiments a silicate of a high-k dielectric layer (e.g., a metal silicate) is formed to lower the k-value of the diffusion barrier by adjusting the silicon content of the silicate while maintaining high film conformality and density.

Abstract: Integrated circuit interconnect structures including a metallization line with a bottom barrier material, and a metallization via lacking a bottom barrier material. Barrier material at a bottom of the metallization line may, along with barrier material on a sidewall of the metallization line, mitigate the diffusion or migration of fill metal from the line. An absence of barrier material at a bottom of the via may reduce via resistance and/or facilitate the use of a highly resistive barrier material that may enhance the scalability of interconnect structures. A number of masking materials and patterning techniques may be integrated into a dual damascene interconnect process to provide for both a barrier material and a low resistance via unburden by the barrier material.

Abstract: Examples herein relate to a memory device comprising an eDRAM memory cell, the eDRAM memory cell can include a write circuit formed at least partially over a storage cell and a read circuit formed at least partially under the storage cell; a compute near memory device bonded to the memory device; a processor; and an interface from the memory device to the processor. In some examples, circuitry is included to provide an output of the memory device to emulate output read rate of an SRAM memory device comprises one or more of: a controller, a multiplexer, or a register. Bonding of a surface of the memory device can be made to a compute near memory device or other circuitry. In some examples, a layer with read circuitry can be bonded to a layer with storage cells. Any layers can be bonded together using techniques described herein.

Abstract: Conformal hermetic dielectric films suitable as dielectric diffusion barriers over 3D topography. In embodiments, the dielectric diffusion barrier includes a dielectric layer, such as a metal oxide, which can be deposited by atomic layer deposition (ALD) techniques with a conformality and density greater than can be achieved in a conventional silicon dioxide-based film deposited by a PECVD process for a thinner contiguous hermetic diffusion barrier. In further embodiments, the diffusion barrier is a multi-layered film including a high-k dielectric layer and a low-k or intermediate-k dielectric layer (e.g., a bi-layer) to reduce the dielectric constant of the diffusion barrier. In other embodiments a silicate of a high-k dielectric layer (e.g., a metal silicate) is formed to lower the k-value of the diffusion barrier by adjusting the silicon content of the silicate while maintaining high film conformality and density.

Abstract: A thin film transistor (TFT) structure includes a gate electrode, a gate dielectric layer on the gate electrode, a channel layer including a semiconductor material with a first polarity on the gate dielectric layer. The TFT structure also includes a multi-layer material stack on the channel layer, opposite the gate dielectric layer, an interlayer dielectric (ILD) material over the multi-layer material stack and beyond a sidewall of the channel layer. The TFT structure further includes source and drain contacts through the interlayer dielectric material, and in contact with the channel layer, where the multi-layer material stack includes a barrier layer including oxygen and a metal in contact with the channel layer, where the barrier layer has a second polarity. A sealant layer is in contact with the barrier layer, where the sealant layer and the ILD have a different composition.

Abstract: Integrated circuit metallization lines having a planar top surface but different vertical heights, for example to control intra-layer resistance/capacitance of integrated circuit interconnect. A hardmask material layer may be inserted between two thicknesses of dielectric material that are over a via metallization. Following deposition of the hardmask material layer, trench openings may be patterned through the hardmask layer to define where line metallization will have a greater height. Following the deposition of a thickness of dielectric material over the hardmask material layer, a trench pattern may be etched through the uppermost thickness of dielectric material, exposing the hardmask material layer wherever the trench does not coincide with an opening in the hardmask material layer. The trench etch may be retarded where the hardmask material layer is exposed, resulting to trenches of differing depth. Trenches of differing depth may be filled with metallization and then planarized.

Abstract: Embodiments disclosed herein include stacked forksheet transistor devices, and methods of fabricating stacked forksheet transistor devices. In an example, an integrated circuit structure includes a backbone. A first transistor device includes a first vertical stack of semiconductor channels adjacent to an edge of the backbone. A second transistor device includes a second vertical stack of semiconductor channels adjacent to the edge of the backbone. The second transistor device is stacked on the first transistor device.

Abstract: An integrated circuit die, a semiconductor structure, and a method of fabricating the semiconductor structure are disclosed. The integrated circuit die includes a substrate and a first anchor and a second anchor disposed on the substrate in a first plane. The integrated circuit die also includes a first wire disposed on the first anchor in the first plane, a third wire disposed on the second anchor in the first plane, and a second wire and a fourth wire suspended above the substrate in the first plane. The second wire is disposed between the first wire and the third wire and the third wire is disposed between the second wire and the fourth wire. The integrated circuit die further includes a dielectric material disposed between upper portions of the first wire, the second wire, the third wire, and the fourth wire to encapsulate an air gap.

Abstract: A first etch stop layer is deposited on a plurality of conductive features on an insulating layer on a substrate. A second etch stop layer is deposited over an air gap between the conductive features. The first etch stop layer is etched to form a via to at least one of the conductive features.

Abstract: An integrated circuit structure comprises a lower device layer that includes a first structure comprising a plurality of PMOS transistors. An upper device layer is formed on the lower device layer, wherein the upper device layer includes a second structure comprising a plurality of NMOS thin-film transistors (TFT).

Abstract: An integrated circuit structure comprises a lower device layer that includes a first structure comprising a plurality of PMOS transistors. An upper device layer is formed on the lower device layer, wherein the upper device layer includes a second structure comprising a plurality of NMOS transistors having a group III-V material source/drain region.

Abstract: A dielectric layer and a method of forming thereof. An opening defined in a dielectric layer and a wire deposited within the opening, wherein the wire includes a core material surrounded by a jacket material, wherein the jacket material exhibits a first resistivity ?1 and the core material exhibits a second resistivity ?2 and ?2 is less than ?1.

Abstract: A device is disclosed. The device includes a first gate conductor, a first source-drain region adjacent a first side of the first gate conductor and a second source-drain region adjacent a second side of the first gate conductor, a second gate conductor below the first gate conductor, a third source-drain region below the first source-drain region and adjacent a first side of the second gate conductor and a fourth source-drain region below the second source-drain region and adjacent a second side of the second gate conductor, a first air gap space between the first source-drain region and a first side of the first gate conductor and a second air gap space between the second source-drain region and the second side of the second gate conductor. A planar dielectric layer is formed above the first gate conductor.

Abstract: A device is disclosed. The device includes a plurality of capacitors, a transistor connected to each of the plurality of capacitors, and a first dielectric layer and a second dielectric layer on respective adjacent sides of adjacent capacitors of the plurality of capacitors. The first dielectric layer and the second dielectric layer include a top portion and a bottom portion, the top portion of the first dielectric layer and the top portion of the second dielectric layer extend from respective directions and meet at a top portion of a space between the adjacent capacitors, the bottom portion of the first dielectric layer and the bottom portion of the second dielectric layer extend from respective directions and meet at a bottom portion of a space between the adjacent capacitors.

Abstract: Embodiments of the present disclosure may generally relate to systems, apparatus, and/or processes to form volumes of oxide within a fin, such as a Si fin. In embodiments, this may be accomplished by applying a catalytic oxidant material on a side of a fin and then annealing to form a volume of oxide. In embodiments, this may be accomplished by using a plasma implant technique or a beam-line implant technique to introduce oxygen ions into an area of the fin and then annealing to form a volume of oxide. Processes described here may be used manufacture a transistor, a stacked transistor, or a three-dimensional (3-D) monolithic stacked transistor.

Abstract: A device is disclosed. The device includes a gate conductor, a first source-drain region and a second source-drain region. The device includes a first air gap space between the first source-drain region and a first side of the gate conductor and a second air gap space between the second source-drain region and a second side of the gate conductor. A hard mask layer that includes holes is under the gate conductor, the first source-drain region, the second source-drain region and the air gap spaces. A planar dielectric layer is under the hard mask.

Abstract: Embodiments disclosed herein include electronic systems with vias that include a horizontal and vertical portion in order to provide interconnects to stacked components, and methods of forming such systems. In an embodiment, an electronic system comprises a board, a package substrate electrically coupled to the board, and a die electrically coupled to the package substrate. In an embodiment the die comprises a stack of components, and a via adjacent to the stack of components, wherein the via comprises a vertical portion and a horizontal portion.

Abstract: A device is disclosed. The device includes a first epitaxial region, a second epitaxial region, a first gate region between the first epitaxial region and a second epitaxial region, a first dielectric structure underneath the first epitaxial region, a second dielectric structure underneath the second epitaxial region, a third epitaxial region underneath the first epitaxial region, a fourth epitaxial region underneath the second epitaxial region, and a second gate region between the third epitaxial region and a fourth epitaxial region and below the first gate region. The device also includes, a conductor via extending from the first epitaxial region, through the first dielectric structure and the third epitaxial region, the conductor via narrower at an end of the conductor via that contacts the first epitaxial region than at an opposite end.