Abstract: A memory device includes a two-dimensional array of access transistors located on a semiconductor substrate; metal interconnect structures embedded in dielectric material layers and electrical connected to electrical nodes of the access transistors; and a two-dimensional array of resistive memory structures embedded in the dielectric material layers. The metal interconnect structures include two first source lines located at a first metal line level and laterally extending along a first horizontal direction; a second source line located at a second metal line level and laterally extending along the first horizontal direction; and a vertical connection structure including a plurality of interconnection via structures and at least one line-level metal structure and providing a vertical electrical connection between the two first source lines and the second source line.

Abstract: The problem of forming a deep trench isolation structure suitable for photodetectors with small pitch is solved by a process in which a grid of trenches is etched from the front side using high energy plasma followed by annealing. The trenches are filled with an oxide followed by etching to recess the oxide. The trench recesses are filled with semiconductor to form a grid-shaped semiconductor structure. After FEOL processing, BEOL processing, attachment to a second substrate, and thinning from the back side, an etch removes the oxide from the back side. The etch stops on the grid-shaped semiconductor structure. The trenches are then lined and filled from the back side. The front side etch allows the trenches to be made narrow and with highly vertical sidewalls. Lining and filling the trenches from the back side provides good optical and electrical isolation.

Abstract: A memory device and a manufacturing method thereof is described. The memory device includes a transistor structure over a substrate and a ferroelectric capacitor structure electrically connected with the transistor structure. The ferroelectric capacitor structure includes a top electrode layer, a bottom electrode layer and a ferroelectric stack sandwiched there-between. The ferroelectric stack includes a first ferroelectric layer, a first stabilizing layer, and one of a second ferroelectric layer or a second stabilizing layer. Materials of the first stabilizing layer and a second stabilizing layer include a metal oxide material.

Abstract: A field effect transistor includes a substrate having a transistor forming region thereon; an insulating layer on the substrate; a first graphene layer on the insulating layer within the transistor forming region; an etch stop layer on the first graphene layer within the transistor forming region; a first inter-layer dielectric layer on the etch stop layer; a gate trench recessed into the first inter-layer dielectric layer and the etch stop layer within the transistor forming region; a second graphene layer on interior surface of the gate trench; a gate dielectric layer on the second graphene layer and on the first inter-layer dielectric layer; and a gate electrode on the gate dielectric layer within the gate trench.

Abstract: A forming operation method of a resistive random access memory is provided. The method includes the following steps. A positive pulse and a negative pulse are sequentially applied, by a bit line/source line driver, to multiple resistive random access memory cells in a direction form a farthest location to a nearest location based on the bit line/source line driver through a bit line and a source line to break down a dielectric film of each of the resistive random access memory cells and generate a conductive filament of each of the resistive random access memory cells.

Abstract: Self-aligned gate cutting techniques are disclosed herein that provide dielectric gate isolation fins for isolating gates of multigate devices from one another. An exemplary device includes a first multigate device having first source/drain features and a first metal gate that surrounds a first channel layer and a second multigate device having second source/drain features and a second metal gate that surrounds a second channel layer. A dielectric gate isolation fin separates the first metal gate from the second metal gate. The dielectric gate isolation fin includes a first dielectric layer having a first dielectric constant and a second dielectric layer having a second dielectric constant disposed over the first dielectric layer. The second dielectric constant is greater than the first dielectric constant. The first metal gate and the second metal gate physically contact the first channel layer and the second channel layer, respectively, and the dielectric gate isolation fin.

Abstract: An antenna device includes a differential-line, a first metal and a second metal. The differential-line includes a first line and a second line. The first metal and second metal are coupled to the first line and second line respectively. The first metal and second metal have different shapes and/or different sizes. The first metal and second metal form symmetric or asymmetric dipole. The first metal and second metal can be disposed on the same plane or different planes, can be electrically insulated and can have a first slot and a second slot respectively. The antenna device can further include a base coupled to the first line and second line. The base can be a daughter board having a front-end module or not. The IC package in daughter board can have different sizes. The daughter board can be offset by different distances and can be coupled to a mother board.

Abstract: Integrated circuits and methods for overlap measure are provided. In an embodiment, an integrated circuit includes a plurality of functional cells including at least one gap disposed adjacent to at least one functional cell of the plurality of functional cells and a first overlay test pattern cell disposed within the at least one gap, wherein the first overlay test pattern cell includes a first number of patterns disposed along a first direction at a first pitch. The first pitch is smaller than a smallest wavelength on a full spectrum of humanly visible lights.

Abstract: A method includes forming a dielectric layer over an epitaxial source/drain region. An opening is formed in the dielectric layer. The opening exposes a portion of the epitaxial source/drain region. A barrier layer is formed on a sidewall and a bottom of the opening. An oxidation process is performing on the sidewall and the bottom of the opening. The oxidation process transforms a portion of the barrier layer into an oxidized barrier layer and transforms a portion of the dielectric layer adjacent to the oxidized barrier layer into a liner layer. The oxidized barrier layer is removed. The opening is filled with a conductive material in a bottom-up manner. The conductive material is in physical contact with the liner layer.

Abstract: A method for fabricating a semiconductor device includes the steps of: providing a substrate having a high-voltage (HV) region and a low-voltage (LV) region; forming a base on the HV region and fin-shaped structures on the LV region; forming a first insulating around the fin-shaped structures; removing the base, the first insulating layer, and part of the fin-shaped structures to form a first trench in the HV region and a second trench in the LV region; forming a second insulating layer in the first trench and the second trench; and planarizing the second insulating layer to form a first shallow trench isolation (STI) on the HV region and a second STI on the LV region.

Abstract: A semiconductor package and a manufacturing method thereof are provided. The semiconductor package includes at least one semiconductor die, an interposer, an encapsulant, a protection layer and connectors. The interposer has a first surface, a second surface opposite to the first surface and sidewalls connecting the first and second surfaces. The semiconductor die is disposed on the first surface of interposer and electrically connected with the interposer. The encapsulant is disposed over the interposer and laterally encapsulating the at least one semiconductor die. The connectors are disposed on the second surface of the interposer and electrically connected with the at least one semiconductor die through the interposer. The protection layer is disposed on the second surface of the interposer and surrounding the connectors. The sidewalls of the interposer include slanted sidewalls connected to the second surface, and the protection layer is in contact with the slant sidewalls of the interposer.

Abstract: A cable connector assembly includes: a mating plug including plural conductive terminals; a circuit board being electrically connected to the mating plug and including: plural terminal pads located at a front of the circuit board and mechanically and electrically connected to the conductive terminals; plural cable pads located at a rear of the circuit board and including plural pairs of high-speed cable pads; and plural conductive traces each connecting a corresponding terminal pad and a corresponding cable pad; and a cable mechanically and electrically connected to the cable pads; wherein the cable includes plural pairs of high-speed wires for transmitting high-speed signals, the conductive traces include plural pairs of high-speed conductive traces connecting the plural pairs of high-speed cable pads and corresponding terminal pads, each pair of high-speed cable pads are connected to a nearest pair of terminal pads.

Abstract: A semiconductor device includes a single diffusion break (SDB) structure dividing a fin-shaped structure into a first portion and a second portion, an isolation structure on the SDB structure, a first spacer adjacent to the isolation structure, a metal gate adjacent to the isolation structure, a shallow trench isolation (STI around the fin-shaped structure, and a second isolation structure on the STI. Preferably, a top surface of the first spacer is lower than a top surface of the isolation structure and a bottom surface of the first spacer is lower than a bottom surface of the metal gate.

Abstract: Various embodiments of the present application are directed towards an integrated chip (IC). The IC comprises a trench capacitor overlying a substrate. The trench capacitor comprises a plurality of capacitor electrode structures, a plurality of warping reduction structures, and a plurality of capacitor dielectric structures. The plurality of capacitor electrode structures, the plurality of warping reduction structures, and the plurality of capacitor dielectric structures are alternatingly stacked and define a trench segment that extends vertically into the substrate. The plurality of capacitor electrode structures comprise a metal component and a nitrogen component. The plurality of warping reduction structures comprise the metal component, the nitrogen component, and an oxygen component.

Abstract: Provided are an information receiving method, an information sending method, a communication node, and a storage medium. The information receiving method includes receiving first information sent by a second communication node, where the first information is configured to instruct the first communication node to initiate propagation delay measurement; and measuring a propagation delay according to the first information.

Abstract: A method for forming a semiconductor device structure is provided. The method includes providing a substrate and a nanostructure stack. The method includes forming an isolation layer over the base and surrounding the fin. The method includes forming a first protection layer over the nanostructure stack and the isolation layer. The method includes forming a second protection layer over the first protection layer. The method includes forming a mask layer over the second protection layer. The top portion of the second protection layer protrudes from the mask layer. The method includes thinning the top portion of the second protection layer. The method includes removing the mask layer. The method includes removing the first protection layer and the second protection layer over the nanostructure stack. The method includes forming a gate stack wrapped around the nanostructure stack.

Abstract: Various embodiments include protection layers for a transistor and methods of forming the same. In an embodiment, a method includes: exposing a semiconductor nanostructure, a dummy nanostructure, and an isolation region by removing a dummy gate; increasing a deposition selectivity between a top surface of the semiconductor nanostructure and a top surface of the isolation region relative a selective deposition process; depositing a protection layer on the top surface of the isolation region by performing the selective deposition process; removing the dummy nanostructure by selectively etching a dummy material of the dummy nanostructure at a faster rate than a protection material of the protection layer; and forming a gate structure around the semiconductor nanostructure.

Abstract: The present invention relates to an LC medium comprising two or more polymerizable compounds, at least one of which contains a substituent comprising a tertiary OH group, to its use for optical, electro-optical and electronic purposes, in particular in LC displays, especially in LC displays of the PSA (polymer sustained alignment) or SA (self-aligning) mode, to an LC display of the PSA or SA mode comprising the LC medium, and to a process of manufacturing the LC display using the LC medium, especially an energy-saving LC display and energy-saving LC display production process.

Abstract: A fastener structure and an assembly method thereof are introduced. The fastener structure includes a body and a fastener. The body has a limiting structure and is for assembling at a first object. The fastener and the body are movably assembled. The fastener has a limiting portion, which coordinates with the limiting structure to limit a movement stroke of the fastener, so as to engage or disengage the fastener with or from a second object. Thus, the body can be assembled with the first object and the fastener can be engaged with or disengaged from the second object so as to complete quick coupling and separation of two objects, further achieving effects of repeated quick coupling and separation.

Abstract: Disclosed in the present invention is a control method for water supply during loosening and conditioning based on a neural network model and a dual parameter correction. The method comprises: establishing a neural network-based model for predicting the amount of water supplied during loosening and conditioning; predicting and distributing the total water supplied; and correcting the model based on material balance calculation and deviation. In the present application, when there is a large deviation in outlet moisture, the dual correction control system combining the material balance calculation and the moisture deviation is used for correction to improve the stability and precise control of the outlet moisture during the loosening and conditioning process.