Abstract: A semiconductor device includes bumps and a plurality of input/output areas on a substrate. Each of the input/output areas include semiconductor elements on the substrate, lower wiring patterns connected to the semiconductor elements, and input/output pins above and connected to the lower wiring patterns. The semiconductor elements provide a logic circuit and a protection circuit. The bumps are above the lower wiring patterns and connected to the input/output pins by upper wiring patterns. The input/output areas include a first input/output area and a second input/output area. The input/output areas includes a first circuit area including the electrostatic discharge protection circuit and a second circuit area including the logic circuit. In the first input/output area, the input/output pin is in the first circuit area. In the second input/output area, the input/output pin is in the second circuit area.

Abstract: An apparatus is provided which comprises: one or more first conductive contacts on a first substrate surface, one or more second conductive contacts on a second substrate surface opposite the first substrate surface, a core layer comprising glass between the first and the second substrate surfaces, and one or more thin film capacitors on the glass core conductively coupled with one of the first conductive contacts and one of the second conductive contacts, wherein the thin film capacitor comprises a first metal layer on a surface of the glass core, a thin film dielectric material on a surface of the first metal layer, and a second metal layer on a surface of the thin film dielectric material. Other embodiments are also disclosed and claimed.

Abstract: A semiconductor device may include a substrate including a cell region and a core/peripheral region. A plurality of bit line structures may be in the cell region of the substrate. A gate structure may be in the core/peripheral regions of the substrate. A lower contact plug and an upper contact plug may be between the bit line structures. The lower contact plug and the upper contact plug may be stacked in a vertical direction. A landing pad pattern may contact an upper sidewall of the upper contact plug. The landing pad pattern may be between an upper portion of the upper contact plug and an upper portion of one of the bit line structures. An upper surface of the landing pad pattern may be higher than an upper surface of each of the bit line structures. A peripheral contact plug may be formed in the core/peripheral regions of the substrate. A wiring may be electrically connected to an upper surface of the peripheral contact plug.

Abstract: A semiconductor device includes a die, an encapsulant over a front-side surface of the die, a redistribution structure on the encapsulant, a thermal module coupled to the back-side surface of the die, and a bolt extending through the redistribution structure and the thermal module. The die includes a chamfered corner. The bolt is adjacent to the chamfered corner.

Abstract: A memory device according to an embodiment of the present disclosure includes: a logic circuit in which a plurality of wiring layers including layers that are different in wiring pitches is stacked; and a memory element that is provided between the plurality of wiring layers.

Abstract: A semiconductor structure includes a semiconductor structure includes a semiconductor die, an insulating encapsulation, a passivation layer and conductive elements. The semiconductor die includes a sensor device and a semiconductor substrate with a first region and a second region adjacent to the first region, and the sensor device is embedded in the semiconductor substrate within the first region. The insulating encapsulation laterally encapsulates the semiconductor die and covers a sidewall of the semiconductor die. The passivation layer is located on the semiconductor die, wherein a recess penetrates through the passivation layer over the first region and is overlapped with the sensor device. The conductive elements are located on the passivation layer over the second region and are electrically connected to the semiconductor die, wherein the passivation layer is between the insulating encapsulation and the conductive elements.

Abstract: The present disclosure provides a method for preparing a semiconductor device with a T-shaped buried gate electrode. The method includes forming an isolation structure in a semiconductor substrate to define an active region, and forming a doped region in the active region. The method also includes etching the semiconductor substrate to form a first trench and a second trench. The first trench has a first portion extending across the doped region and a second portion extending away from the first portion, and the second trench has a third portion extending across the doped region and a fourth portion extending away from the third portion. The method further includes forming a first gate electrode in the first trench and a second gate electrode in the second trench.

Abstract: A memory device includes a substrate, a buried word line, a connecting structure, an air gap, and a first dielectric layer. The buried word line is disposed in the substrate. The connecting structure is disposed on the buried word line. The air gap is disposed on the buried word line and is adjacent to the connecting structure. The first dielectric layer is disposed on the connecting structure and the air gap, wherein the buried word line, the connecting structure, and the first dielectric layer are disposed in the first direction, which is substantially perpendicular to the top surface of the substrate.

Abstract: A method includes attaching an integrated circuit chip module substrate to a printed circuit board (PCB). First region(s) of a bottom surface of the module include electrical contacts to the board, and second region(s) of the bottom surface of the module lack such contacts. Mechanical structures are assembled into the second regions. These structures allow lateral motion of the module relative to the board, and are sized and placed to inhibit bending of the second regions of the module towards the board under application of a vertical force on a top surface of the module. A package for an integrated circuit may be assembled using the method.

Abstract: A fan-out semiconductor package includes: an interconnection member including a first insulating layer, first and second pads respectively disposed on opposite sides of the first insulating layer and a first via connecting the first and second pads to each other; a semiconductor chip disposed on the interconnection member; and an encapsulant encapsulating at least portions of the semiconductor chip. A center line of the first via is out of alignment with at least one of a center line of the first pad and a center line of the second pad.

Abstract: In accordance with the disclosure, an inductor may be formed over a semiconductor substrate of one or both dies in a face-to-face die arrangement while reducing the parasitic capacitance between the inductor and the adjacent die. In disclosed embodiments, a semiconductor device may include a void (e.g., an air gap) between the inductor and the adjacent die to reduce the parasitic capacitance between the inductor and the adjacent die. The void may be formed in the die that includes the inductor and/or the adjacent die. In some respects, the void may be etched in interface layers (e.g., comprising bump pads and dielectric material) between the semiconductor dies, and may extend along the length of the inductor.

Abstract: A method of forming semiconductor device is disclosed. A substrate having a logic circuit region and a memory cell region is provided. A first transistor with a first gate is formed in the logic circuit region and a second transistor with a second gate is formed in the memory cell region. A stressor layer is deposited to cover the first transistor in the logic circuit region and the second transistor in the memory cell region. The first transistor and the second transistor are subjected to an annealing process under the influence of the stressor layer to recrystallize the first gate and the second gate.

Abstract: A multi-chip package and a manufacturing method thereof are provided. The multi-chip package includes a redistribution circuit structure; a first semiconductor chip disposed on the redistribution structure and having a first active surface on which a first conductive post is disposed; a second semiconductor chip disposed above the first semiconductor chip and having a second active surface on which a first conductor is disposed; and a first encapsulant disposed on the redistribution circuit structure and encapsulating at least the first semiconductor chip, wherein the first conductive post and the first conductor are aligned and bonded to each other to electrically connect the first semiconductor chip and the second semiconductor chip.

Abstract: A package includes an integrated circuit. The integrated circuit includes a first chip, a second chip, a third chip, and a fourth chip. The second chip and the third chip are disposed side by side on the first chip. The second chip and the third chip are hybrid bonded to the first chip. The fourth chip is fusion bonded to at least one of the second chip and the third chip.

Abstract: LED packages are disclosed capable of emitting a range of colors including white light, while still emitting that can have a high color rendering index (CRI). The LED packages can have a simplified reflective cup arrangement and improved lead frame design. The LED packages according to the present invention comprise one or more LED WITH PHOSPHORs for high CRI lighting applications, along with multiple narrowband emitters (e.g. RGB LEDs), but do not have a dam or partition to segregate the LED WITH PHOSPHOR from the multiple emitters. This results in a LED package that is less complex and easier to manufacture, while still providing the desired flexibility in LED package emissions.

Abstract: A method includes forming a buffer dielectric layer over a carrier, and forming a first dielectric layer and a first redistribution line over the buffer dielectric layer. The first redistribution line is in the first dielectric layer. The method further includes performing a planarization on the first dielectric layer to level a top surface of the first dielectric layer, forming a metal post over and electrically coupling to the first redistribution line, and encapsulating the metal post in an encapsulating material. The encapsulating material contacts a top surface of the planarized top surface of the first dielectric layer.

Abstract: A semiconductor device including a substrate having isolation films and active regions that are defined by the isolation films. The active regions extend in a first direction. A first trench is disposed on the substrate. Second trenches are disposed in the active regions. A filling film is disposed in the first trench. First gate patterns are disposed on the filling film in the first trench. Second gate patterns are disposed in the second trenches. The second gate patterns extend in a second direction that is different from the first direction. The filling film includes at least one material selected from a semiconductor material film and a metal.

Abstract: One or more semiconductor processing tools may form a deep trench within a silicon wafer. The one or more semiconductor processing tools may deposit a first insulating material within the deep trench. The one or more semiconductor processing tools may form, after forming the deep trench with the silicon wafer, a shallow trench above the deep trench. The one or more semiconductor processing tools may deposit a second insulating material within the shallow trench.

Abstract: The present disclosure provides a semiconductor device with a T-shaped buried gate electrode and a method for forming the semiconductor device. The semiconductor device includes a semiconductor substrate having an active region, and a first gate electrode disposed in the semiconductor substrate. The semiconductor device also includes a first source/drain region and a second source/drain region disposed in the active region and at opposite sides of the first gate electrode. The first gate electrode has a first portion extending across the active region and a second portion extending into the first source/drain region.

Abstract: A semiconductor memory device including first-first conductive lines on a substrate; second-first conductive lines on the first-first conductive lines; first contacts connected to the first-first conductive lines; and second contacts connected to the second-first conductive lines, wherein the first-first conductive lines protrude in a first direction beyond the second-first conductive lines; the first-first conductive lines include first regions having a first thickness, second regions having a second thickness, the second thickness being greater than the first thickness, and third regions having a third thickness, the third thickness being smaller than the first thickness and smaller than the second thickness, and the second regions of the first-first conductive lines are between the first regions of the first-first conductive lines and the third regions of the first-first conductive lines.