Abstract: The present invention discloses embodiments of a semiconductor chip with one or more bottom external (power or ground) connections, a front side power network layer, a device layer, and a grind side power network layer. The device layer has a plurality of devices. One or more of the devices has one or more device power connections and one or more device ground connections and the device layer has a front side and a back grind side. The front side power network layer has power, ground, signal, and other connections that connect to respective device power and device ground connections from/through the top front side layer. In like manner, power, ground, signal, and other connections connect to respective device power and device ground connections from/through the bottom of grind side power network layer. (Alternative, e.g., external conduit connections are disclosed.

Abstract: An interconnect for a semiconductor device includes a laminate substrate; a first plurality of electrical devices in or on a surface of the laminate substrate; a redistribution layer having a surface disposed on the surface of the laminate substrate; a second plurality of electrical devices in or on the surface of the redistribution layer; and a plurality of transmission lines between the first plurality of electrical devices and the second plurality of electrical devices. The surface of the laminate substrate and the surface of the redistribution layer are parallel to each other to form a dielectric structure and a conductor structure.

Abstract: A lidded chip package apparatus has reduced latent thermal stress in an under-chip high-CTE layer of the chip package because the lid of the package was adhered to a substrate of the package and cured during a same thermal excursion as when underfill was dispensed and cured under a chip of the package, and the chip package was cooled from the combined underfill and lidding process to room temperature with the lid adhered to the chip and the substrate, thereby reducing latent thermal stress in the under-chip high-CTE layer of the chip package.

Abstract: A semiconductor device including a hybrid contact scheme for stacked FET is disclosed with integration of a BSPDN. A double-sided (both frontside and backside of the wafer) contact scheme with buried power rail (BPR) and backside power distribution network (BSPDN) provides optimum contact and interconnect. The stacked FET could include, for example, FINFET over FINFET, FINFET over nanosheet, or nanosheet over nanosheet.

Abstract: A multichip module with a vertical stack of a logic chip, a translator chip, and at least one memory chip. The multichip module includes a logic chip, a translator chip over and vertically connecting to the logic chip, and at least one memory chip above and vertically connecting to the translator chip where the translator chip is one of a chip with active devices or a passive chip.

Abstract: A method of manufacturing a semiconductor device is provided. The method includes forming a first recess partially through a substrate from a first side of the substrate, forming a dielectric layer in the first recess, forming a second recess partially through the dielectric layer from the first side of the substrate, and forming a buried power rail (BPR) in the second recess of the dielectric layer. The method also includes thinning the substrate from a second side of the substrate to a level of the dielectric layer, the second side of the substrate being opposite to the first side of the substrate.

Abstract: An approach to provide a method of joining a semiconductor chip to a semiconductor substrate, the approach includes depositing a nanoparticle paste and aligning each of one or more solder contacts on a semiconductor chip to a substrate bond pad. The approach includes sintering, in a reducing gaseous environment, the nanoparticle paste to connect the semiconductor chip to a semiconductor substrate bond pad.

Abstract: A method for fabricating a bridge chip assembly for interconnecting two or more IC dies is provided. Each of the IC dies has a first region including first connections having a first pitch and has a second region including second connections or connection pads having a second pitch, the first pitch being greater than the second pitch. The method includes: attaching a non-conductive underfill film on an upper surface of at least the second region of each of the IC dies; bonding the second connections/connection pads of a first IC die to corresponding first connection pads/connections of a bridge chip; and bonding the second connections/connection pads of a second IC die to the bridge chip. The bridge chip assembly includes the bridge chip bonded with the first and second IC dies, and the non-conductive underfill film disposed between the bridge chip and the IC dies.

Abstract: An exemplary method includes at a bonding temperature, bonding a semiconductor chip to an organic laminate substrate using solder; without cooldown from the bonding temperature to room temperature, at an underfill dispense temperature, dispensing underfill between the semiconductor chip and the organic laminate substrate; and curing the underfill within a range of temperatures above the underfill dispense temperature. Another exemplary method includes depositing a first solder on pads of an organic laminate substrate; contacting a second solder on pillars of a semiconductor chip to the first solder on the pads of the organic laminate substrate; and solder bonding the semiconductor chip to the organic laminate substrate.

Abstract: A lidded chip package apparatus has reduced latent thermal stress in an under-chip high-CTE layer of the chip package because the lid of the package was adhered to a substrate of the package and cured during a same thermal excursion as when underfill was dispensed and cured under a chip of the package, and the chip package was cooled from the combined underfill and lidding process to room temperature with the lid adhered to the chip and the substrate, thereby reducing latent thermal stress in the under-chip high-CTE layer of the chip package.

Abstract: A method of fabricating a semiconductor structure includes forming a scissionable layer that is able to absorb infrared (IR) radiation, below a first carrier wafer. A first hard-dielectric layer is formed below the scissionable layer. A second hard-dielectric layer is formed on a top surface of a semiconductor wafer. The first dielectric layer is bonded with the second dielectric layer. Connectors on a bottom portion of the semiconductor wafer are formed to provide an electric connection to the semiconductor wafer. A second carrier wafer is connected to the connectors on the bottom portion of the semiconductor wafer. The first carrier wafer is separated from the semiconductor wafer by degrading the scissionable layer with an IR, by passing the IR through the first carrier wafer. A back end of line (BEOL) wiring passing from a top surface of the semiconductor wafer through the first and second dielectric layers is provided.

Abstract: A method of fabricating a semiconductor structure includes forming a scissionable layer that is able to absorb infrared (IR) radiation, below a first carrier wafer. A first hard-dielectric layer is formed below the scissionable layer. A second hard-dielectric layer is formed on a top surface of a semiconductor wafer. The first dielectric layer is bonded with the second dielectric layer. Connectors on a bottom portion of the semiconductor wafer are formed to provide an electric connection to the semiconductor wafer. A second carrier wafer is connected to the connectors on the bottom portion of the semiconductor wafer. The first carrier wafer is separated from the semiconductor wafer by degrading the scissionable layer with an IR, by passing the IR through the first carrier wafer. A back end of line (BEOL) wiring passing from a top surface of the semiconductor wafer through the first and second dielectric layers is provided.

Abstract: A method of fabricating an under-bump metallurgy (UBM) structure that is free of gold processing includes forming a titanium layer on top of a far back of line (FBEOL) of a semiconductor. A first copper layer is formed on top of the titanium layer. A photoresist (PR) layer is formed on top of the first copper layer between traces of the FBEOL to provide a cavity to the FBEOL traces. A top copper layer is formed on top of the first copper layer. A protective surface layer (PSL) is formed on top of the top copper layer.

Abstract: A method for fabricating a bridge chip assembly for interconnecting two or more IC dies is provided. Each of the IC dies has a first region including first connections having a first pitch and has a second region including second connections or connection pads having a second pitch, the first pitch being greater than the second pitch. The method includes: attaching a non-conductive underfill film on an upper surface of at least the second region of each of the IC dies; bonding the second connections/connection pads of a first IC die to corresponding first connection pads/connections of a bridge chip; and bonding the second connections/connection pads of a second IC die to the bridge chip. The bridge chip assembly includes the bridge chip bonded with the first and second IC dies, and the non-conductive underfill film disposed between the bridge chip and the IC dies.

Abstract: A method of forming a planarized integration structure is provided. The method includes forming at least two conductive pillars on a packaging substrate, wherein the packaging substrate has a positive or convex meniscus shape. The method further includes placing a bridging die on the packaging substrate between an adjacent pair of the at least two conductive pillars, wherein the bridging die includes one or more conductive interconnects. The method further includes forming a cover layer on the substrate over the at least two conductive pillars and the bridging die, and planarizing the conductive pillars and the one or more conductive interconnects.

Abstract: Copper (Cu)-to-Cu bonding techniques for high bandwidth interconnects on a bridge chip attached to chips which are further attached to a packaging substrate are provided. In one aspect, a method of forming an interconnect structure is provided. The method includes: bonding individual chips to at least one bridge chip via Cu-to-Cu bonding to form a multi-chip structure; and bonding the multi-chip structure to a packaging substrate via solder bonding, after the Cu-to-Cu bonding has been performed, to form the interconnect structure including the individual chips bonded to the at least one bridge chip and to the packaging substrate. A structure formed by the method is also provided.

Abstract: Techniques for simultaneously plating features of varying sizes on a semiconductor substrate are provided. In one aspect, a method for electroplating includes: placing a shield over a wafer, offset from a surface of the wafer, which covers portions of the wafer and leaves other portions of the wafer uncovered; and depositing at least one metal onto the wafer by electroplating to simultaneously form metallurgical features of varying sizes on the wafer based on the shield altering local deposition rates for the portions of the wafer covered by the shield. An electroplating apparatus is also provided.

Abstract: A semiconductor wafer includes a first substrate and a first etch stop layer formed on the first substrate. The etch stop layer has an opening. The semiconductor wafer further includes a second substrate and a second etch stop layer formed on the second substrate. The first substrate is bonded on top of the second substrate such that the first etch stop layer is positioned between the first substrate and the second substrate. A trench is formed in the opening.

Abstract: Copper (Cu)-to-Cu bonding techniques for high bandwidth interconnects on a bridge chip attached to chips which are further attached to a packaging substrate are provided. In one aspect, a method of forming an interconnect structure is provided. The method includes: bonding individual chips to at least one bridge chip via Cu-to-Cu bonding to form a multi-chip structure; and bonding the multi-chip structure to a packaging substrate via solder bonding, after the Cu-to-Cu bonding has been performed, to form the interconnect structure including the individual chips bonded to the at least one bridge chip and to the packaging substrate. A structure formed by the method is also provided.

Abstract: Techniques for simultaneously plating features of varying sizes on a semiconductor substrate are provided. In one aspect, a method for electroplating includes: placing a shield over a wafer, offset from a surface of the wafer, which covers portions of the wafer and leaves other portions of the wafer uncovered; and depositing at least one metal onto the wafer by electroplating to simultaneously form metallurgical features of varying sizes on the wafer based on the shield altering local deposition rates for the portions of the wafer covered by the shield. An electroplating apparatus is also provided.