Abstract: Embodiments herein relate to scaling of Static Random Access Memory (SRAM) cells. An SRAM cell include nMOS transistors on one level above pMOS transistors on a lower level. Transistors on the two levels can have overlapping footprints to save space. Additionally, the SRAM cell can use pMOS access transistors in place of nMOS access transistors to allow reuse of areas of the cell which would otherwise be used by the nMOS access transistors. In one approach, gate interconnects are provided in these areas, which have an overlapping footprint with underlying pMOS access transistors to save space. The SRAM cells can be connected to bit lines and word lines in overhead and/or bottom metal layers. In another aspect, SRAM cells of a column are connected to bit lines in an overlying M0 metal layer and an underlying BM0 metal layers to reduce capacitance.

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: An apparatus including a circuit structure including a device stratum including a plurality of devices including a first side and an opposite second side; and a metal interconnect coupled to at least one of the plurality of devices from the second side of the device stratum. A method including forming a transistor device including a channel between a source region and a drain region and a gate electrode on the channel defining a first side of the device; and forming an interconnect to one of the source region and the drain region from a second side of the device.

Abstract: Stacked transistor structures having a conductive interconnect between source/drain regions of upper and lower transistors. In some embodiments, the interconnect is provided, at least in part, by highly doped epitaxial material deposited in the upper transistor's source/drain region. In such cases, the epitaxial material seeds off of an exposed portion of semiconductor material of or adjacent to the upper transistor's channel region and extends downward into a recess that exposes the lower transistor's source/drain contact structure. The epitaxial source/drain material directly contacts the lower transistor's source/drain contact structure, to provide the interconnect. In other embodiments, the epitaxial material still seeds off the exposed semiconductor material of or proximate to the channel region and extends downward into the recess, but need not contact the lower contact structure.

Abstract: Microelectronic assemblies, and related devices and methods, are disclosed herein. For example, in some embodiments, a microelectronic assembly may include a die having a front side and a back side, the die comprising a first material and conductive contacts at the front side; and a thermal layer attached to the back side of the die, the thermal layer comprising a second material and a conductive pathway, wherein the conductive pathway extends from a front side of the thermal layer to a back side of the thermal layer.

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.

Abstract: An integrated circuit structure comprises a lower device layer that includes a first structure comprising a first set of transistor fins and a first set of contact metallization. An upper device layer is bonded onto the lower device layer, where the upper device layer includes a second structure comprising a second set of transistor fins and a second set of contact metallization. At least one power isolation wall extends from a top of the upper device layer to the bottom of the lower device layer, wherein the power isolation wall is filled with a conductive material such that power is routed between transistor devices on the upper device layer and the lower device layer.

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: Techniques are provided herein to form semiconductor devices having a non-reactive metal contact in an epi region of a stacked transistor configuration. An n-channel device may be located vertically above a p-channel device (or vice versa). Source or drain regions are adjacent to both ends of the n-channel device and the p-channel device, such that a source or drain region of one device is located vertically over the source or drain region of the other device. A deep and narrow contact may be formed from either the frontside or the backside of the integrated circuit through the stacked source or drain regions. According to some embodiments, the contact is formed using a refractory metal or other non-reactive metal such that no silicide or germanide is formed with the epi material of the source or drain regions at the boundary between the contact and the source or drain regions.

Abstract: Techniques are provided herein to form gate-all-around (GAA) semiconductor devices utilizing a metal fill in an epi region of a stacked transistor configuration. In one example, an n-channel device and the p-channel device may both be GAA transistors each having any number of nanoribbons extending in the same direction where the n-channel device is located vertically above the p-channel device (or vice versa). Source or drain regions are adjacent to both ends of the n-channel device and the p-channel device. A metal fill may be provided around the source or drain region of the bottom semiconductor device to provide a high contact area between the highly conductive metal fill and the epitaxial material of that source or drain region. Metal fill may also be used around the top source or drain region to further improve conductivity throughout both of the stacked source or drain regions.

Abstract: Techniques are provided herein to form semiconductor devices having a frontside and backside contact in an epi region of a stacked transistor configuration. In one example, an n-channel device and a p-channel device may both be GAA transistors where the n-channel device is located vertically above the p-channel device (or vice versa). Source or drain regions are adjacent to both ends of the n-channel device and the p-channel device. Deep and narrow contacts may be formed from both the frontside and the backside of the integrated circuit through the stacked source or drain regions. The contacts may physically contact each other to form a combined contact that extends through an entirety of the stacked source or drain regions. The higher contact area provided to both source or drain regions provides a more robust ohmic contact with a lower contact resistance compared to previous contact architectures.

Abstract: Techniques to form wrap-around contacts in a stacked transistor architecture. An example includes a first source or drain region and a second source or drain region spaced from and over the first source or drain region. A conductive contact is on a top surface of the second source or drain and extends down one or more side surfaces of the second source or drain region such that the conductive contact is laterally adjacent to a bottom surface of the second source or drain region. In some cases, the conductive contact is also on a top surface of the first source or drain region, and/or extends down a side surface of the first source or drain region. In some cases, a second conductive contact is on a bottom surface of the first source or drain region, and may extend up a side surface the first source or drain region.

Abstract: Techniques are provided herein to form semiconductor devices having conductive backside structures to couple various transistor structures. In some embodiments, a given conductive backside structure acts as a shunt interconnect between two transistors, such as between the gate of one transistor and the source or drain region of another transistor. In an example, an integrated circuit includes two transistor devices having semiconductor material extending between separate source and drain regions and different gate structures over or around the semiconductor material of the two transistor devices. A conductive backside structure may be formed from the backside of the integrated circuit (e.g., after removing all or most of the substrate), where the backside structure contacts the source or drain region of one transistor and the gate structure of the other transistor.

Abstract: Disclosed herein are stacked transistors having device strata with different channel widths, as well as related methods and devices. In some embodiments, an integrated circuit structure may include stacked strata of transistors, wherein different channel materials of different strata have different widths.

Abstract: Techniques are provided herein to form semiconductor devices having a stacked transistor configuration. An n-channel device and a p-channel device may both be gate-all-around (GAA) transistors each having any number of nanoribbons extending in the same direction where one device is located vertically above the other device. According to some embodiments, the n-channel device and the p-channel device conductively share the same gate, and a width of the gate structure around one device is greater than the width of the gate structure around the other device. According to some other embodiments, the n-channel device and the p-channel device each have a separate gate structure that is isolated from the other using a dielectric layer between them. A gate contact is adjacent to the upper device and contacts the gate structure of the other lower device.

Abstract: A device is disclosed. The device includes a first semiconductor fin, a first source-drain epitaxial region adjacent a first portion of the first semiconductor fin, a second source-drain epitaxial region adjacent a second portion of the first semiconductor fin, a first gate conductor above the first semiconductor fin, a gate spacer covering the sides of the gate conductor, a second semiconductor fin below the first semiconductor fin, a second gate conductor on a first side of the second semiconductor fin and a third gate conductor on a second side of the second semiconductor fin, a third source-drain epitaxial region adjacent a first portion of the second semiconductor fin, and a fourth source-drain epitaxial region adjacent a second portion of the second semiconductor fin. The device also includes a dielectric isolation structure below the first semiconductor fin and above the second semiconductor fin that separates the first semiconductor fin and the second semiconductor fin.

Abstract: Embodiments disclosed herein include a semiconductor device. In an embodiment, the semiconductor device comprises a first transistor strata. The first transistor strata comprises a first backbone, a first transistor adjacent to a first edge of the first backbone, and a second transistor adjacent to a second edge of the first backbone. In an embodiment, the semiconductor device further comprises a second transistor strata over the first transistor strata. The second transistor strata comprises a second backbone, a third transistor adjacent to a first edge of the second backbone, and a fourth transistor adjacent to a second edge of the second backbone.

Abstract: Embodiments herein describe techniques for an integrated circuit (IC). The IC may include a lower device layer that includes a first transistor structure, an upper device layer above the lower device layer including a second transistor structure, and an isolation wall that extends between the upper device layer and the lower device layer. The isolation wall may be in contact with an edge of a first gate structure of the first transistor structure and an edge of a second gate structure of the second transistor structure, and may have a first width to the edge of the first gate structure at the lower device layer, and a second width to the edge of the second gate structure at the upper device layer. The first width may be different from the second width. Other embodiments may be described and/or claimed.

Abstract: Metallization structures under a semiconductor device layer. A metallization structure in alignment with semiconductor fin may be on a side of the fin opposite a gate stack. Backside and/or frontside substrate processing techniques may be employed to form such metallization structures on a bottom of a semiconductor fin or between bottom portions of two adjacent fins. Such metallization structures may accompany interconnect metallization layers that are over a gate stack, for example to increase metallization layer density for a given number of semiconductor device layers.

Abstract: An apparatus is provided which comprises: a fin; a layer formed on the fin, the layer dividing the fin in a first section and a second section; a first device formed on the first section of the fin; and a second device formed on the second section of the fin.