Abstract: A computing system with graphics processor boosting is shown. The computing system has a graphics processing unit controlling a display, a code memory storing instructions, and a processor operating the graphics processing unit to control the display. The processor is configured to execute the instructions retrieved from the code memory to implement a plurality of graphics processor boosting modules for the graphics processing unit, and implement an activation controller that controls activation of the different graphics processor boosting modules through different configuration interfaces with balances between the different graphics processor boosting modules.

Abstract: Semiconductor devices and methods of forming the same are provided. In one embodiment, a semiconductor device includes a gate structure sandwiched between and in contact with a first spacer feature and a second spacer feature, a top surface of the first spacer feature and a top surface of the second spacer feature extending above a top surface of the gate structure, a gate self-aligned contact (SAC) dielectric feature over the first spacer feature and the second spacer feature, a contact etch stop layer (CESL) over the gate SAC dielectric feature, a dielectric layer over the CESL, a gate contact feature extending through the dielectric layer, the CESL, the gate SAC dielectric feature, and between the first spacer feature and the second spacer feature to be in contact with the gate structure, and a liner disposed between the first spacer feature and the gate contact feature.

Abstract: To reduce a thickness variation of a spin-on coating (SOC) layer that is applied over a plurality of first and second trenches with different pattern densities as a bottom layer in a photoresist stack, a two-step thermal treatment process is performed on the SOC layer. A first thermal treatment step in the two-step thermal treatment process is conducted at a first temperature below a cross-linking temperature of the SOC layer to cause flow of the SOC layer, and a second thermal treatment step in the two-step thermal treatment process is conducted at a second temperature to cause cross-linking of the SOC layer.

Abstract: Semiconductor structures and methods of forming the same are provided. In one embodiment, a semiconductor structure includes an active region over a substrate, a gate structure disposed over the active region, and a gate contact that includes a lower portion disposed over the gate structure and an upper portion disposed over the lower portion.

Abstract: A semiconductor structure includes a metal gate structure (MG) formed over a substrate, a first gate spacer formed on a first sidewall of the MG, a second gate spacer formed on a second sidewall of the MG opposite to the first sidewall, where the second gate spacer is shorter than the first gate spacer, a source/drain (S/D) contact (MD) adjacent to the MG, where a sidewall of the MD is defined by the second gate spacer, and a contact feature configured to electrically connect the MG to the MD.

Abstract: A memory device including a first semiconductor die and a memory cube mounted on and connected with the first semiconductor die is described. The memory cube includes multiple stacked tiers, and each tier of the multiple stacked tiers includes second semiconductor dies laterally wrapped by an encapsulant and a redistribution structure disposed on the second semiconductor dies and the encapsulant. The second semiconductor dies of the multiple stacked tiers are electrically connected with the first semiconductor die through the redistribution structures in the multiple stacked tiers.

Abstract: A method includes etching a first portion and a second portion of a dummy gate stack to form a first opening and a second opening, respectively, and depositing a silicon nitride layer to fill the first opening and the second opening. The deposition of the silicon nitride layer comprises a first process selected from treating the silicon nitride layer using hydrogen radicals, implanting the silicon nitride layer, and combinations thereof. The method further includes etching a third portion of the dummy gate stack to form a trench, etching a semiconductor fin underlying the third portion to extend the trench down into a bulk portion of a semiconductor substrate underlying the dummy gate stack, and depositing a second silicon nitride layer into the trench.

Abstract: An interconnect fabrication method is disclosed herein that utilizes a disposable etch stop hard mask over a gate structure during source/drain contact formation and replaces the disposable etch stop hard mask with a dielectric feature (in some embodiments, dielectric layers having a lower dielectric constant than a dielectric constant of dielectric layers of the disposable etch stop hard mask) before gate contact formation. An exemplary device includes a contact etch stop layer (CESL) having a first sidewall CESL portion and a second sidewall CESL portion separated by a spacing and a dielectric feature disposed over a gate structure, where the dielectric feature and the gate structure fill the spacing between the first sidewall CESL portion and the second sidewall CESL portion. The dielectric feature includes a bulk dielectric over a dielectric liner. The dielectric liner separates the bulk dielectric from the gate structure and the CESL.

Abstract: Semiconductor package includes interposer, dies, encapsulant. Each die includes active surface, backside surface, side surfaces. Backside surface is opposite to active surface. Side surfaces join active surface to backside surface. Encapsulant includes first material and laterally wraps dies. Dies are electrically connected to interposer and disposed side by side on interposer with respective backside surfaces facing away from interposer. At least one die includes an outer corner. A rounded corner structure is formed at the outer corner. The rounded corner structure includes second material different from first material. The outer corner is formed by backside surface and a pair of adjacent side surfaces of the at least one die. The side surfaces of the pair have a common first edge. Each side surface of the pair does not face other dies and has a second edge in common with backside surface of the at least one die.

Abstract: A display method for an electronic label having a display area is disclosed. The display method includes the following steps. A plurality of visual contents to be displayed are predefined, wherein each of the visual contents has a first state and a second state corresponding to a first state display subpage and a second state display page respectively. The display area is divided into a plurality of first sub-areas for displaying the plurality of first state display subpages respectively. A second sub-area operable for selection of a specific one from the plurality of first state display subpages is provided in each of the first sub-area in response to a first instruction of a user. The display area is caused to display the second state display page corresponding to the specific first state display subpage in response to a second instruction of the user.

Abstract: A memory device including a first semiconductor die and a memory cube mounted on and connected with the first semiconductor die is described. The memory cube includes multiple stacked tiers, and each tier of the multiple stacked tiers includes second semiconductor dies laterally wrapped by an encapsulant and a redistribution structure disposed on the second semiconductor dies and the encapsulant. The second semiconductor dies of the multiple stacked tiers are electrically connected with the first semiconductor die through the redistribution structures in the multiple stacked tiers.

Abstract: Various embodiments of the present disclosure are directed towards an image sensor device including a first image sensor element and a second image sensor element disposed within a substrate. An interconnect structure is disposed along a front-side surface of the substrate and comprises a plurality of conductive wires, a plurality of conductive vias, and a first absorption structure. The first image sensor element is configured to generate electrical signals from electromagnetic radiation within a first range of wavelengths. The second image sensor element is configured to generate electrical signals from the electromagnetic radiation within a second range of wavelengths that is different than the first range of wavelengths. The second image sensor element is laterally adjacent to the first image sensor element. Further, the first image sensor element overlies the first absorption structure and is spaced laterally between opposing sidewalls of the first absorption structure.

Abstract: A method and structure directed to providing a source/drain isolation structure includes providing a device having a first source/drain region adjacent to a second source/drain region. A masking layer is deposited between the first and second source/drain regions and over an exposed first part of the second source/drain region. After depositing the masking layer, a first portion of an ILD layer disposed on either side of the masking layer is etched, without substantial etching of the masking layer, to expose a second part of the second source/drain region and to expose the first source/drain region. After etching the first portion of the ILD layer, the masking layer is etched to form an L-shaped masking layer. After forming the L-shaped masking layer, a first metal layer is formed over the exposed first source/drain region and a second metal layer is formed over the exposed second part of the second source/drain region.

Abstract: A method includes placing a wafer into a process chamber, and depositing a silicon nitride layer on a base layer of the wafer. The process of depositing the silicon nitride layer includes introducing a silicon-containing precursor into the process chamber, purging the silicon-containing precursor from the process chamber, introducing hydrogen radicals into the process chamber, purging the hydrogen radicals from the process chamber; introducing a nitrogen-containing precursor into the process chamber, and purging the nitrogen-containing precursor from the process chamber.

Abstract: The present disclosure relates to an integrated chip including a substrate and a pixel. The pixel includes a photodetector. The photodetector is in the substrate. The integrated chip further includes a first inner trench isolation structure and an outer trench isolation structure that extend into the substrate. The first inner trench isolation structure laterally surrounds the photodetector in a first closed loop. The outer trench isolation structure laterally surrounds the first inner trench isolation structure along a boundary of the pixel in a second closed loop and is laterally separated from the first inner trench isolation structure. Further, the integrated chip includes a scattering structure that is defined, at least in part, by the first inner trench isolation structure and that is configured to increase an angle at which radiation impinges on the outer trench isolation structure.

Abstract: A device includes a substrate, a gate structure wrapping around a vertical stack of nanostructure semiconductor channels, and a source/drain abutting the vertical stack and in contact with the nanostructure semiconductor channels. The device includes a gate via in contact with the first gate structure. The gate via includes a metal liner layer having a first flowability, and a metal fill layer having a second flowability higher than the first flowability.

Abstract: Some embodiments relate to a CMOS image sensor disposed on a substrate. A plurality of pixel regions comprising a plurality of photodiodes, respectively, are configured to receive radiation that enters a back-side of the substrate. A boundary deep trench isolation (BDTI) structure is disposed at boundary regions of the pixel regions, and includes a first set of BDTI segments extending in a first direction and a second set of BDTI segments extending in a second direction perpendicular to the first direction to laterally surround the photodiode. The BDTI structure comprises a first material. A pixel deep trench isolation (PDTI) structure is disposed within the BDTI structure and overlies the photodiode. The PDTI structure comprises a second material that differs from the first material, and includes a first PDTI segment extending in the first direction such that the first PDTI segment is surrounded by the BDTI structure.

Abstract: A method includes providing a structure having source/drain electrodes and a first dielectric layer over the source/drain electrodes; forming a first etch mask covering a first area of the first dielectric layer; performing a first etching process to the first dielectric layer, resulting in first trenches over the source/drain electrodes; filling the first trenches with a second dielectric layer that has a different material than the first dielectric layer; removing the first etch mask; performing a second etching process including isotropic etching to the first area of the first dielectric layer, resulting in a second trench above a first one of the source/drain electrodes; depositing a metal layer into at least the second trench; and performing a chemical mechanical planarization (CMP) process to the metal layer.

Abstract: A gel composition includes an oleogel dispersed within an aqueous gel which is continuous phase. the oleogel comprising either a plant-based oil in liquid state at room temperature and a wax, or a plant-based oil in non-liquid state at room temperature. and the aqueous gel comprising water and at least one of protein and polysaccharide. The present disclosure also discloses an edible composition comprising the gel composition, and the use of this edible composition as an animal fat substitute. The present disclosure further discloses a food product comprising the edible composition. Methods for making the gel composition are also disclosed.

Abstract: A semiconductor device structure is provided. The semiconductor device structure includes a transistor on a substrate, a contact electrically connected to a source/drain feature of the transistor, a first dielectric layer on a gate stack of the transistor, a second dielectric layer on the contact, a gate spacer layer between the gate stack of the transistor and the contact, and a contact liner between the gate spacer layer and the contact. A top of the contact liner is located higher than a bottom surface of the second dielectric layer and lower than a top surface of the second dielectric layer.