Abstract: The present disclosure relates to use of 10?(Z), 13?(E), 15?(E)-Heptadecatrienyl hydroquinone compound (hereafter “HQ17(3)”) represented by the following Formula (12), a pharmaceutically acceptable salt, and/or a solvate and/or a hydrate thereof, and a pharmaceutical composition comprising the above compound, in treating coronavirus infection and diseases caused by the infection, especially SARS-COV-2 infection.

Abstract: A self-powered display device includes a display module and a power module. The display module is a cholesteric liquid crystal display module, and the power module is a solar cell module. The display module allows light to enter the power module from the front side, and the power module generates electricity upon receiving the light to provide the necessary energy for the display module to show images. The power module has multiple active areas and multiple inactive areas between the active areas. When the width of the inactive area is less than or equal to 50 ?m, the human eye will have difficulty discerning the width of the inactive area. Additionally, a shielding layer can be placed on the inactive area to ensure that the visual color difference (?E) between the inactive area and the active area does not exceed 10 color difference units, thereby improving the image quality.

Abstract: Various embodiments of the present disclosure are directed towards a method for forming an integrated chip. An alignment process is performed on a first semiconductor workpiece and a second semiconductor workpiece by virtue of a plurality of workpiece pins. The first semiconductor workpiece is bonded to the second semiconductor workpiece. A shift value is determined between the first and second semiconductor workpieces by virtue of a first plurality of alignment marks on the first semiconductor workpiece and a second plurality of alignment marks on the second semiconductor workpiece. A layer of an integrated circuit (IC) structure is formed over the second semiconductor workpiece based at least in part on the shift value.

Abstract: An interposer includes a substrate having an inductor forming region thereon, a plurality of trenches within the inductor forming region in the substrate, a buffer layer lining interior surfaces of the plurality of trenches and forming air gaps within the plurality of trenches, and an inductor coil pattern embedded in the buffer layer within the inductor forming region.

Abstract: Aspects of the invention enhance the capabilities of the Message as a Platform (“MaaP”) by adding interfaces thereto so that the platform directly interfaces with the Online Charging System (“OCS”), the Policy and Charging Rules Function (“PCRF”), the Equipment Identity Register (“EIR”), the Cloud Database (“COB”) and the Home Subscriber Server (“HSS”) without middle layer or without using Rich Communication Services (“RCS”) as an intermediary. Moreover, embodiments of the invention may create a user interface of the MaaP so that users may configure parameters to interact with the network nodes right from the user interface.

Abstract: A structure of an MIM capacitor and a heat sink include a dielectric layer. The dielectric layer includes a capacitor region and a heat dispensing region. A bottom electrode is embedded in the dielectric layer. A first heat conductive layer covers the dielectric layer. A capacitor dielectric layer is disposed on the first heat conductive layer within the capacitor region. A second heat conductive layer covers and contacts the capacitor dielectric layer and the first heat conductive layer. A top electrode is disposed within the capacitor region and the heat dispensing region and covers the second heat conductive layer. A first heat sink is disposed within the heat dispensing region and contacts the top electrode. A second heat sink is disposed within the heat dispensing region and contacts the first heat conductive layer and the second heat conductive layer.

Abstract: A metal-insulator-metal capacitor includes a bottom electrode, a dielectric layer, a superlattice layer, a silicon dioxide layer and a top electrode stacked from bottom to top. The superlattice layer contacts the dielectric layer. A silicon dioxide layer has a negative voltage coefficient of capacitance.

Abstract: A memory device includes a substrate, a memory unit disposed on the substrate, a first spacer layer, and a second spacer layer. The memory unit includes a first electrode, a second electrode disposed above the first electrode, and a memory material layer disposed between the first electrode and the second electrode. The first spacer layer is disposed on a sidewall of the memory unit and includes a first portion disposed on a sidewall of the first electrode, a second portion disposed on a sidewall of the second electrode, and a bottom portion. A thickness of the second portion is greater than that of the first portion. The second spacer layer is disposed on the first spacer layer. A material composition of the second spacer layer is different from that of the first spacer layer. The bottom portion is disposed between the substrate and the second spacer layer.

Abstract: A method of removing a step height on a gate structure includes providing a substrate. A gate structure is disposed on the substrate. A dielectric layer covers the gate structure and the substrate. Then, a composite material layer is formed to cover the dielectric layer. Later, part of the composite material layer is removed to form a step height disposed directly on the gate structure. Subsequently, a wet etching is performed to remove the step height. After the step height is removed, the dielectric layer is etched to form a first contact hole to expose the gate structure.

Abstract: A method for fabricating a semiconductor device includes the steps of forming a gate structure on a substrate, forming an interlayer dielectric (ILD) layer on the gate structure, forming a contact hole in the ILD layer adjacent to the gate structure, performing a plasma doping process to form a doped layer in the ILD layer and a source/drain region adjacent to the gate structure, forming a conductive layer in the contact hole, planarizing the conductive layer to form a contact plug, removing the doped layer to form an air gap adjacent to the contact plug, and then forming a stop layer on the ILD layer and the contact plug.

Abstract: Various embodiments of the present application are directed towards a metal-insulator-metal (MIM) capacitor. The MIM capacitor comprises a bottom electrode disposed over a semiconductor substrate. A top electrode is disposed over and overlies the bottom electrode. A capacitor insulator structure is disposed between the bottom electrode and the top electrode. The capacitor insulator structure comprises at least three dielectric structures vertically stacked upon each other. A bottom half of the capacitor insulator structure is a mirror image of a top half of the capacitor insulator structure in terms of dielectric materials of the dielectric structures.

Abstract: An isolation structure of a semiconductor device includes a substrate, a first isolation structure and a second isolation structure. The substrate has a first region and a second region, and there is a boundary between the first region and the second region. The first isolation structure is disposed in the first region of the substrate, and the first isolation structure includes a dielectric liner and a first insulating layer. The second isolation structure is disposed in the second region of the substrate, and the second isolation structure includes a second insulating layer. The first isolation structure and the second isolation structure are respectively located on both sides of the boundary.

Abstract: In some implementations described herein, a capacitor structure may include a metal-insulator-metal structure in which work function metal layers are included between the insulator layer of the capacitor structure and the conductive electrode layers of the capacitor structure. The work function metal layers may enable high-k dielectric materials to be used for the insulator layer in that the work function metal layers may provide an increased electron barrier height between the insulator layer and the conductive electrode layers, which may increase the breakdown voltage and may reduce the current leakage for the capacitor structure.

Abstract: A manufacturing method of a memory device includes following steps. A memory unit including a first electrode, a second electrode, and a memory material layer is formed on a substrate. The second electrode is disposed above the first electrode in a vertical direction. The memory material layer is disposed between the first electrode and the second electrode in the vertical direction. A first spacer layer including a first portion, a second portion, and a third portion is formed on a sidewall of the memory unit. The first portion is disposed on a sidewall of the first electrode. The second portion is disposed on a sidewall of the second electrode. The third portion is disposed above the memory unit in the vertical direction and connected with the second portion. A thickness of the second portion in a horizontal direction is greater than that of the first portion in the horizontal direction.

Abstract: An electronic apparatus includes: an electronic panel comprising a display unit comprising a plurality of pixels and a sensing unit comprising a plurality of sensing electrodes; and an electronic module overlapping with the electronic panel when viewed in a plan view, the sensing unit comprising: a base substrate comprising a hole area overlapping with the electronic module, an active area overlapping with the sensing electrodes, and a peripheral area adjacent to the active area; a connection line in the hole area and connected to a portion of the sensing electrodes; and a conductive light blocking pattern in the hole area and spaced apart from the connection line and the sensing electrodes.

Abstract: The present disclosure relates to a composition for inducing immune response comprising a glycoengineered antibody or antigen-binding fragment thereof that is specific for an antigen portion having a receptor binding domain (RBD) of a surface protein of a virus. The present disclosure also relates to an immune combination and a method for treating an infection by a virus.

Abstract: A resistive memory device includes a dielectric layer, a trench, a first resistive switching element, a diode via structure, and a signal line structure. The trench is disposed in the dielectric layer. The first resistive switching element is disposed in the trench. The first resistive switching element includes a first bottom electrode, a first top electrode disposed above the first bottom electrode, and a first variable resistance layer disposed between the first bottom electrode and the first top electrode. The diode via structure is disposed in the dielectric layer and located under the trench, and the diode via structure is connected with the first bottom electrode. The signal line structure is disposed in the trench, a part of the signal line structure is disposed on the first resistive switching element, and the signal line structure is electrically connected with the first top electrode.

Abstract: A semiconductor device with a deep trench isolation and a shallow trench isolation includes a substrate. The substrate is divided into a high voltage transistor region and a low voltage transistor region. A deep trench is disposed within the high voltage transistor region. The deep trench includes a first trench and a second trench. The first trench includes a first bottom. The second trench extends from the first bottom toward a bottom of the substrate. A first shallow trench and a second shallow trench are disposed within the low voltage transistor region. A length of the first shallow trench is the same as a length of the second trench. An insulating layer fills in the first trench, the second trench, the first shallow trench and the second shallow trench.

Abstract: A power supply device includes a control board disposed within the chassis. An input connector and an output connector are disposed within the chassis and are electrically connected to the control board. A fan module includes a fan frame and a fan connector disposed on the outer surface of the fan frame. A flexible printed circuit board includes a conducting section, a fan connecting section and a lighting connecting section. The conducting section is electrically connected to the control board, fan connecting section and the lighting connecting section. The fan connecting section is electrically connected to the fan connector. The light-guiding handle is coupled to the chassis and disposed on the lighting connecting section to face the light-guiding handle.

Abstract: The present invention relates to a cholesteric liquid crystal display device, and a control method. The cholesteric liquid crystal display device includes a cholesteric liquid crystal display module, a solar battery unit, and a control unit. The control unit further includes an ambient energy management module and an energy storage module. The solar battery unit provides electrical energy to the management module. And the ambient energy management module stores electrical energy in the energy storage module. When it is necessary to refresh the images of the cholesteric liquid crystal display module, and the potential difference of the energy storage module reaches the charging cut-off voltage. The energy storage module can discharge the stored electrical energy to provide the electrical energy required by the cholesteric liquid crystal display module to refresh the image.