Abstract: Embodiments include a wafer-on-wafer bonding where each wafer includes a seal ring structure around die areas defined in the wafer. Embodiments provide a further seal ring spanning the interface between the wafers. Embodiments may extend the existing seal rings of the wafers, provide an extended seal ring structure separate from the existing seal rings of the wafers, or combinations thereof.

Abstract: A method includes the following steps. A photoresist is exposed to a first light-exposure through a first mask, wherein the first mask includes a first stitching region, and a portion of the photoresist corresponding to a portion of the first stitching region is unexposed during the first light-exposure. The photoresist is exposed to a second light-exposure through a second mask, wherein the second mask includes a second stitching region and a functional feature in the second stitching region, and the portion of the photoresist is exposed by the functional feature during the second light-exposure.

Abstract: An ESD protection device protects a circuit from TLPs between a first terminal and a second terminal. The device includes an NPN discharge structure and a PNP triggering device. The first terminal is coupled to the p-doped emitter and the n-doped base of the PNP triggering device and also the n-doped emitter of the NPN discharge structure. The second terminal is coupled to the n-doped collector of the NPN discharge structure. The p-doped collector of the PNP triggering device is coupled to the p-doped base of the NPN discharge structure. A TLP causes base-collector junction breakdown in the PNP triggering device, which results in a current through the PNP triggering device. That current is injected into the base of the NPN discharge structure, which results in a larger discharge current through the NPN discharge structure. The device provides high holding voltage ESD protection device with snapback.

Abstract: Some embodiments of the present application are directed towards an integrated circuit (IC). The integrated circuit includes a semiconductor substrate having a peripheral region and a memory cell region separated by an isolation structure. The isolation structure extends into a top surface of the semiconductor substrate and comprises dielectric material. A logic device is arranged on the peripheral region. A memory device is arranged on the memory region. The memory device includes a gate electrode and a memory hardmask over the gate electrode. An anti-dishing structure is disposed on the isolation structure. An upper surface of the anti-dishing structure and an upper surface of the memory hardmask have equal heights as measured from the top surface of the semiconductor substrate.

Abstract: A bio-field effect transistor (bioFET) system includes a bioFET configured to receive to a first voltage signal and output a current signal, where the current signal varies exponentially with respect to the first voltage signal. A logarithmic current-to-time converter is connected to the bioFET and is configured to receive the current signal and convert the current signal to a time domain signal. The time domain signal varies logarithmically with respect to the current signal, such that the time domain signal varies linearly with respect to the first voltage signal.

Abstract: A method of forming a semiconductor device includes forming a fin protruding above a substrate; forming a liner over the fin; performing a surface treatment process to convert an upper layer of the liner distal to the fin into a conversion layer, the conversion layer comprising an oxide or a nitride of the liner; forming isolation regions on opposing sides of the fin after the surface treatment process; forming a gate dielectric over the conversion layer after forming the isolation regions; and forming a gate electrode over the fin and over the gate dielectric.

Abstract: In a method of manufacturing a semiconductor device, a fin structure is formed over a substrate. The fin structure is sculpted to have a plurality of non-etched portions and a plurality of etched portions having a narrower width than the plurality of non-etched portions. The sculpted fin structure is oxidized so that a plurality of nanowires are formed in the plurality of non-etched portions, respectively, and the plurality of etched portions are oxidized to form oxides. The plurality of nanowires are released by removing the oxides.

Abstract: The present disclosure provides an optical structure and a method for fabricating an optical structure, the method includes forming a light detection region in a substrate, forming an isolation structure at surrounding the light detection region, and forming a primary grid over the isolation structure, including forming a metal layer over the isolation structure, forming a first dielectric layer over the metal layer, and partially removing the metal layer and the first dielectric layer with a first mask by patterning, and forming a secondary grid at least partially surrounded by the primary grid laterally.

Abstract: A device includes a redistribution structure, including conductive features; dielectric layers; and an internal support within a first dielectric layer of the dielectric layers, wherein the internal support is free of passive and active devices; a first interconnect structure attached to a first side of the redistribution structure; a second interconnect structure attached to the first side of the redistribution structure, wherein the second interconnect structure is laterally adjacent the first interconnect structure, wherein the internal support laterally overlaps both the first interconnect structure and the second interconnect structure.

Abstract: A method of making a semiconductor device includes depositing a TiN layer over a substrate. The method further includes doping a first portion of the TiN layer using an oxygen-containing plasma treatment. The method further includes doping a second portion of the TiN layer using a nitrogen-containing plasma treatment, wherein the second portion of the TiN layer directly contacts the first portion of the TiN layer. The method further includes forming a first metal gate electrode over the first portion of the TiN layer. The method further includes forming a second metal gate electrode over the second portion of the TiN layer, wherein the first metal gate electrode has a different work function from the second metal gate electrode, and the second metal gate electrode directly contacts the first metal gate electrode.

Abstract: The present disclosure describes a semiconductor structure that includes a channel region, a source region adjacent to the channel region, a drain region, a drift region adjacent to the drain region, and a dual gate structure. The dual gate structure includes a first gate structure over portions of the channel region and portions of the drift region. The dual gate structure also includes a second gate structure over the drift region.

Abstract: A method of manufacturing a semiconductor device includes providing a carrier, disposing a first pad on the carrier, forming a post on the first pad, and disposing a joint adjacent to the post and the first pad to form a first entire contact interface between the first pad and the joint and a second entire contact interface between the first pad and the post. The first entire contact interface and the second entire contact interface are flat surfaces.

Abstract: A coupling system includes an optical fiber configured to carry an optical signal. The coupling system further includes a chip in optical communication with the optical fiber. The chip includes a substrate. The chip further includes a grating on a first side of the substrate, wherein the grating is configured to receive the optical signal. The chip further includes an interconnect structure over the grating on the first side of the substrate, wherein the interconnect structure defines a cavity aligned with the grating. The chip further includes a first polysilicon layer on a second side of the substrate, wherein the second side of the substrate is opposite to the first side of the substrate.

Abstract: A method includes providing a structure having a first channel member and a second channel member over a substrate. The first channel member is located in a first region of the structure and the second channel member is located in a second region of the structure. The method also includes forming a first oxide layer over the first channel member and a second oxide layer over the second channel member, forming a first dielectric layer over the first oxide layer and a second dielectric layer over the second oxide layer, and forming a capping layer over the second dielectric layer but not over the first dielectric layer. The method further includes performing an annealing process to increase a thickness of the second oxide layer under the capping layer.

Abstract: Provided are a package structure and a method of forming the same. The package structure includes a first die, a second die group, an interposer, an underfill layer, a thermal interface material (TIM), and an adhesive pattern. The first die and the second die group are disposed side by side on the interposer. The underfill layer is disposed between the first die and the second die group. The adhesive pattern at least overlay the underfill layer between the first die and the second die group. The TIM has a bottom surface being in direct contact with the first die, the second die group, and the adhesive pattern. The adhesive pattern separates the underfill layer from the TIM.

Abstract: A semiconductor structure includes a first transistor, a second transistor, a first dummy source/drain, a third transistor, a fourth transistor, and a second dummy source/drain. The first transistor and a second transistor adjacent to the first transistor are at a first elevation. The first dummy source/drain is disposed at the first elevation. The third transistor and a fourth transistor adjacent to the third transistor, are at a second elevation different from the first elevation. The second dummy source/drain is disposed at the second elevation. The second transistor is vertically aligned with the third transistor. The first dummy source/drain is vertically aligned with a source/drain of the fourth transistor. The second dummy source/drain is vertically aligned with a source/drain of the first transistor. The gate structure between the second dummy source/drain and a source/drain of the third transistor is absent. A method for manufacturing a semiconductor structure is also provided.

Abstract: A memory integrated circuit is provided. The memory integrated circuit includes a first memory array, a second memory array and a driving circuit. The first and second memory arrays are laterally spaced apart, and respectively include: memory cells, each including an access transistor and a storage capacitor coupled to the access transistor; bit lines, respectively coupled to a row of the memory cells; and word lines, respectively coupled to a column of the memory cells. The driving circuit is disposed below the first and second memory arrays, and includes sense amplifiers. Each of the bit lines in the first memory array and one of the bit lines in the second memory array are routed to input lines of one of the sense amplifiers.

Abstract: Disclosed are metal-insulator-metal capacitors and integrated chips. In one embodiment, a metal-insulator-metal capacitor includes N electrodes and (N?1) passivation layers, wherein the N electrodes and the (N?1) passivation layers are alternately stacked on a substrate. N is an integer larger than 1. Thicknesses of the N electrodes gradually increase in a direction parallel to a normal direction of the substrate.

Abstract: Various examples of an integrated circuit device and a method for forming the device are disclosed herein. In an example, a method includes receiving a workpiece that includes a substrate, and a device fin extending above the substrate. The device fin includes a channel region. A portion of the device fin adjacent the channel region is etched, and the etching creates a source/drain recess and forms a dielectric barrier within the source/drain recess. The workpiece is cleaned such that a bottommost portion of the dielectric barrier remains within a bottommost portion of the source/drain recess. A source/drain feature is formed within the source/drain recess such that the bottommost portion of the dielectric barrier is disposed between the source/drain feature and a remainder of the device fin.

Abstract: Structures and methods for trench isolation are disclosed. In one example, a silicon-on-insulator (SOI) structure is disclosed. The SOI structure includes: a substrate, a dielectric layer and a polysilicon region. The substrate includes: a handle layer, an insulation layer arranged over the handle layer, a buried layer arranged over the insulation layer, and a trench extending downward from an upper surface of the buried layer and terminating in the handle layer. The dielectric layer is located on a bottom surface of the trench and contacting the handle layer. The polysilicon region is located in the trench and contacting the dielectric layer.