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: Transistor structures may include a metal oxide contact buffer between a portion of a channel material and source or drain contact metallization. The contact buffer may improve control of transistor channel length by limiting reaction between contact metallization and the channel material. The channel material may be of a first composition and the contact buffer may be of a second composition.

Abstract: N-type gate-all-around (nanosheet, nanoribbon, nanowire) field-effect transistors (GAAFETs) vertically stacked on top of p-type GAAFETs in complementary FET (CFET) devices comprise non-crystalline silicon layers that form the n-type transistor source, drain, and channel regions. The non-crystalline silicon layers can be formed via deposition, which can provide for a simplified processing flow to form the middle dielectric layer between the n-type and p-type GAAFETs relative to processing flows where the silicon layers forming the n-type transistor source, drain, and channel regions are grown epitaxially.

Abstract: A method for manufacturing integrated circuit (IC) devices includes forming first and second mask patterns with overlapping and non-overlapping features. Non-overlapping features may be removed before etching a target material layer. A third mask pattern may be formed from the overlapping features and used to etch a target material layer. The third mask pattern may be employed to make regular arrays of substantially rectangular structures. An IC device may include an IC die, an array of structures on a layer of the IC die, and multiple groups of parallel stripes of indentations or depressions in the layer. The structures may each include a transistor and a capacitor.

Abstract: An integrated circuit device comprising a resistor formed on a non-crystalline substrate, the resistor comprising a gate electrode; a gate dielectric in contact with the gate electrode; a source electrode and a drain electrode; and a thin film transistor TFT channel material coupled between the source electrode and the drain electrode.

Abstract: An integrated circuit device comprising a plurality of first field effect transistors (FETs) formed on a substrate, wherein a first FET comprises a first channel material comprising a portion of the substrate; and a plurality of second FETs formed on the substrate, wherein a second FET comprises a second channel material that is different from the first channel material, wherein the second channel material comprises a thin film transistor (TFT) channel material.

Abstract: A high performance (HP) thin film transistor (TFT) architecture to enable fabricating backside memory after metallization starts, or as part of back end of line (BEOL) processes. The HP TFT material is suitable for fabricating the memory stack at the lower BEOL temperatures while still delivering the switching speed requirements of a 3D memory stack in the CIM component. A through silicon via (TSV) architecture connects the logic and the memory in the die.

Abstract: The present disclosure may be directed to a computer-assisted or autonomous driving (CA/AD) vehicle that receives a plurality of indications of a condition of one or more features of a plurality of locations of a roadway, respectively, encoded in a plurality of navigation signals broadcast by a plurality of transmitters as the CA/AD vehicle drives past the locations enroute to a destination. The CA/AD vehicle may then determine, based in part on the received indications, driving adjustments to be made and send indications of the driving adjustments to a driving control unit of the CA/AD vehicle.

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: 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: Transistor structures may include a metal oxide contact buffer between a portion of a channel material and source or drain contact metallization. The contact buffer may improve control of transistor channel length by limiting reaction between contact metallization and the channel material. The channel material may be of a first composition and the contact buffer may be of a second composition.

Abstract: Transistor structures may include a metal oxide contact buffer between a portion of a channel material and source or drain contact metallization. The contact buffer may improve control of transistor channel length by limiting reaction between contact metallization and the channel material. The channel material may be of a first composition and the contact buffer may be of a second composition.

Abstract: Methods and apparatus to provide power management for multi-die stacks using artificial intelligence are disclosed. An example integrated circuit (IC) package includes a computer processor unit (CPU) die, a memory die, inference engine circuitry within the CPU die, the inference engine circuitry to infer, based on a first machine learning model, a workload for at least one of the CPU die or the memory die, and power management engine circuitry within the CPU die, the power management engine circuitry distinct from the inference engine circuitry, the power management engine circuitry to adjust, based on a second machine learning model different than the first machine learning model, operational parameters associated with the at least one of the CPU die or the memory die, the inferred workload to be an input to the second machine learning model.

Abstract: A vertical transistor structure includes a material stack having a source material, a drain material, and a channel material therebetween. The vertical transistor structure further includes a gate electrode adjacent to a sidewall of the stack, where the sidewall includes the channel material, and at least a partial thickness of both the source material and the drain material. A gate dielectric is present between the sidewall of the stack and the gate electrode. The vertical transistor structure further includes a first metallization over a first area of the stack above the gate dielectric layer, and in contact with the gate electrode on sidewall of the stack. A second metallization is adjacent to the first metallization, where the second metallization is over a second area of the stack, and in contact with the source material or the drain material.

Abstract: Composite IC chip including a chiplet embedded within metallization levels of a host IC chip. The chiplet may include a device layer and one or more metallization layers interconnecting passive and/or active devices into chiplet circuitry. The host IC may include a device layer and one or more metallization layers interconnecting passive and/or active devices into host chip circuitry. Features of one of the chiplet metallization layers may be directly bonded to features of one of the host IC metallization layers, interconnecting the two circuitries into a composite circuitry. A dielectric material may be applied over the chiplet. The dielectric and chiplet may be thinned with a planarization process, and additional metallization layers fabricated over the chiplet and host chip, for example to form first level interconnect interfaces. The composite IC chip structure may be assembled into a package substantially as a monolithic IC chip.

Abstract: A composite integrated circuit (IC) device structure comprising a host chip and a chiplet. The host chip comprises a first device layer and a first metallization layer. The chiplet comprises a second device layer and a second metallization layer that is interconnected to transistors of the second device layer. A top metallization layer comprising a plurality of first level interconnect (FLI) interfaces is over the chiplet and host chip. The chiplet is embedded between a first region of the first device layer and the top metallization layer. The first region of the first device layer is interconnected to the top metallization layer by one or more conductive vias extending through the second device layer or adjacent to an edge sidewall of the chiplet.

Abstract: Methods and apparatus to provide power management for multi-die stacks using artificial intelligence are disclosed. An example integrated circuit (IC) package includes a computer processor unit (CPU) die, a memory die, inference engine circuitry within the CPU die, the inference engine circuitry to infer, based on a first machine learning model, a workload for at least one of the CPU die or the memory die, and power management engine circuitry within the CPU die, the power management engine circuitry distinct from the inference engine circuitry, the power management engine circuitry to adjust, based on a second machine learning model different than the first machine learning model, operational parameters associated with the at least one of the CPU die or the memory die, the inferred workload to be an input to the second machine learning model.

Abstract: Methods and apparatus to implement efficient memory storage in multi-die packages are disclosed. An example multi-die package includes a multi-die stack including a first die and a second die. The second die is stacked on the first die. The multi-die package further includes a third die adjacent the multi-die stack. The multi-die package also includes a silicon-based connector to communicatively couple the multi-die stack and the third die. The silicon-based connector includes at least one of a logic circuit or a memory circuit.

Abstract: Methods and apparatus to provide power management for multi-die stacks using artificial intelligence are disclosed. An example multi-die package includes a computer processor unit (CPU) die, a memory die stacked in vertical alignment with the CPU die, and artificial intelligence (AI) architecture circuitry to infer a workload for at least one of the CPU die or the memory die. The AI architecture circuitry is to manage power consumption of at least one of the CPU die or the memory die based on the inferred workload.

Abstract: Memory devices in which a memory cell includes a thin film select transistor and a capacitor (1TFT-1C). A 2D array of metal-insulator-metal capacitors may be fabricated over an array of the TFTs. Adjacent memory cells coupled to a same bitline may employ a continuous stripe of thin film semiconductor material. An isolation transistor that is biased to remain off may provide electrical isolation between adjacent storage nodes of a bitline. Wordline resistance may be reduced with a wordline shunt fabricated in a metallization level and strapped to gate terminal traces of the TFTs at multiple points over a wordline length. The capacitor array may occupy a footprint over a substrate. The TFTs providing wordline and bitline access to the capacitors may reside substantially within the capacitor array footprint. Peripheral column and row circuitry may employ FETs fabricated over a substrate substantially within the capacitor array footprint.