Abstract: A method of preparing an air gap includes: forming a first covering layer etching and removing part higher than a horizontal line where a top of the oxide layer is located; forming a first oxide layer on an etched plane; etching the first oxide layer; removing a part of the first oxide layer; reserving a rest part of the first oxide layer; taking a reserved first oxide layer as an oxide layer pattern; forming a second covering layer at a position of a removed part of the first oxide layer; removing the oxide layer pattern and the oxide layer.

Abstract: A magnetoresistive random access memory (MRAM) cell includes a bottom electrode, a magnetic tunnel junction structure, a bipolar tunnel junction selector; and a top electrode. The tunnel junction selector includes a MgO tunnel barrier layer and provides a bipolar function for putting the MTJ structure in parallel or anti-parallel mode.

Abstract: A semiconductor device includes a first memory cell and a dummy region adjacent to the first memory cell. The first memory cell includes a first transistor. The dummy region includes a cut-off transistor. The cut-off transistor has a first terminal electrically coupled to a second terminal of the first transistor. The cut-off transistor has a third terminal electrically coupled to ground.

Abstract: The present disclosure relates to an integrated chip including a semiconductor device. The semiconductor device includes a first source/drain structure, a second source/drain structure, a stack of channel structures, and a gate structure. The stack of channel structures and the gate structure are between the first and second source/drain structures. The gate structure surrounds the stack of channel structures. A first conductive wire overlies and is spaced from the semiconductor device. The first conductive wire includes a first stack of conductive layers. A first conductive contact extends through a dielectric layer from the first conductive wire to the first source/drain structure. The first conductive contact is on a back-side of the first source/drain structure.

Abstract: Embodiments herein may describe techniques for an integrated circuit including a MOSFET having a source area, a channel area, a gate electrode, and a drain area. The channel area may include a first channel region with a dopant of a first concentration next to the source area, and a second channel region with the dopant of a second concentration higher than the first concentration next to the drain area. A source electrode may be in contact with the source area, a gate oxide layer above the channel area, and the gate electrode above the gate oxide layer. A first resistance exists between the source electrode and the gate electrode. A second resistance exists between the source electrode, the gate electrode, and a path through the gate oxide layer to couple the source electrode and the gate electrode after a programming operation is performed. Other embodiments may be described and/or claimed.

Abstract: A package substrate is disclosed. The package substrate includes a die package in the package substrate located at least partially underneath a location of a power delivery interface in a die that is coupled to the surface of the package substrate. Connection terminals are accessible on a surface of the die package to provide connection to the die that is coupled to the surface of the package substrate. Metal-insulator-metal layers inside the die package are coupled to the connection terminals.

Abstract: A semiconductor structure includes a substrate; an isolation structure over the substrate; a first fin extending from the substrate and through the isolation structure; a first source/drain structure over the first fin; a contact etch stop layer over the isolation structure and contacting a first side face of the first source/drain structure; and a first dielectric structure contacting a second side face of the first source/drain structure. The first side face and the second side face are on opposite sides of the first fin in a cross-sectional view cut along a widthwise direction of the first fin. The first dielectric structure extends higher than the first source/drain structure.

Abstract: The present disclosure describes a method of forming a semiconductor device having epitaxial structures with optimized dimensions. The method includes forming first and second fin structures on a substrate, forming a spacer layer on the first and second fin structures, forming a first spacer structure adjacent to the first fin structure, and forming a first epitaxial structure adjacent to the first spacer structure. The first and second fin structures are separated by an isolation layer. The first spacer structure has a first height above the isolation layer. The method further includes forming a second spacer structure adjacent to the second fin structure and forming a second epitaxial structure adjacent to the second spacer structure. The second spacer structure has a second height above the isolation layer greater than the first height. The second epitaxial structure includes a type of dopant different from the first epitaxial structure.

Abstract: A semiconductor structure includes a substrate having a first well of a first conductivity type and a second well of a second conductivity type. From a top view, the first well includes first and seconds edges extending along a first direction. The second edge has multiple turns, resulting in the first well having a protruding section and a recessed section. The semiconductor structure further includes a first source/drain feature over the protruding section and a second source/drain feature over a main body of the first well. The first source/drain feature is of the first conductivity type. The second source/drain feature is of the second conductivity type. The first and the second source/drain features are generally aligned along a second direction perpendicular to the first direction from the top view.

Abstract: An OLED display panel may include a substrate, an OLED light emitter on the substrate and configured to emit light, and a visible light sensor on the substrate and configured to detect at least a portion of the emitted light based on reflection of the portion of the emitted light from a recognition target. The visible light sensor is in a non-light emitting region adjacent to the OLED light emitter so as to be horizontally aligned with the OLED light emitter in a horizontal direction extending parallel to an upper surface of the substrate, or between the substrate and a non-light emitting region adjacent to the OLED light emitter such that the visible light sensor is vertically aligned with the non-light emitting region in a vertical direction extending perpendicular to the upper surface of the substrate.

Abstract: A semiconductor structure includes an isolation structure, a source or drain region over the isolation structure, a channel layer connecting to the source or drain region, a gate structure over the isolation structure and engaging the channel layer, an isolating layer below the channel layer and the gate structure, a dielectric cap below the isolating layer, and a contact structure having a first portion and a second portion. The first portion of the contact structure extends through the isolation structure, and the second portion of the contact structure extends from the first portion of the contact structure, through the dielectric cap and the isolating layer, and to the source or drain region. The first portion of the contact structure is below the second portion and wider than the second portion.

Abstract: A semiconductor structure includes at least two field effect transistors. A gate strip including a plurality of gate dielectrics and a gate electrode strip can be formed over a plurality of semiconductor active regions. Source/drain implantation is conducted using the gate strip as a mask. The gate strip is divided into gate electrodes after the implantation.

Abstract: A cavity may be formed in a dielectric material layer overlying a substrate. A layer stack including a metallic barrier liner, a metallic fill material layer, and a metallic capping material may be deposited in the cavity and over the dielectric material layer. Portions of the layer stack located above a horizontal plane including a top surface of the dielectric material layer may be removed. A contiguous set of remaining material portions of the layer stack includes a metal interconnect structure that is free of a pitted surface.

Abstract: A method of controlling the forming voltage of a dielectric film in a resistive random access memory (ReRAM) device. The method includes depositing a dielectric film contains intrinsic defects on a substrate, forming a plasma-excited treatment gas containing H2 gas, and exposing the dielectric film to the plasma-excited treatment gas to create additional defects in the dielectric film without substantially changing a physical thickness of the dielectric film, where the additional defects lower the forming voltage needed for generating an electrically conducting filament across the dielectric film. The dielectric film can include a metal oxide film and the plasma-excited treatment gas may be formed using a microwave plasma source.

Abstract: Wrap-around contact structures for semiconductor fins, and methods of fabricating wrap-around contact structures for semiconductor fins, are described. In an example, an integrated circuit structure includes a semiconductor fin having a first portion protruding through a trench isolation region. A gate structure is over a top and along sidewalls of the first portion of the semiconductor fin. A source or drain region is at a first side of the gate structure, the source or drain region including an epitaxial structure on a second portion of the semiconductor fin. The epitaxial structure has substantially vertical sidewalls in alignment with the second portion of the semiconductor fin. A conductive contact structure is along sidewalls of the second portion of the semiconductor fin and along the substantially vertical sidewalls of the epitaxial structure.

Abstract: An integrated circuit (IC) structure includes a substrate, a transistor, an interconnect structure, a plurality of metal lines, an oxide liner, a passivation layer, and a nitride layer. The transistor is on the substrate. The interconnect structure is over the transistor. The metal lines is on the interconnect structure. The oxide liner is over the plurality of metal lines. The passivation layer is over the oxide liner and is more porous than the passivation layer. The nitride layer is over the passivation layer.

Abstract: Dual self-aligned gate endcap (SAGE) architectures, and methods of fabricating dual self-aligned gate endcap (SAGE) architectures, are described. In an example, an integrated circuit structure includes a first semiconductor fin having a cut along a length of the first semiconductor fin. A second semiconductor fin is parallel with the first semiconductor fin. A first gate endcap isolation structure is between the first semiconductor fin and the second semiconductor fin. A second gate endcap isolation structure is in a location of the cut along the length of the first semiconductor fin.

Abstract: In an embodiment, a device includes a first fin extending from a substrate. The device also includes a first gate stack over and along sidewalls of the first fin. The device also includes a first gate spacer disposed along a sidewall of the first gate stack. The device also includes and a first source/drain region in the first fin and adjacent the first gate spacer, the first source/drain region including a first epitaxial layer on the first fin, the first epitaxial layer having a first dopant concentration of boron. The device also includes and a second epitaxial layer on the first epitaxial layer, the second epitaxial layer having a second dopant concentration of boron, the second dopant concentration being greater than the first dopant concentration.

Abstract: The present disclosure relates to an integrated chip that includes a substrate, a first metal line, and a hybrid metal line. The first metal line includes a first metal material and is within a first interlayer dielectric (ILD) layer over the substrate. The hybrid metal line is also within the first ILD layer. The hybrid metal line includes a pair of first metal segments that comprise the first metal material. The hybrid metal line further includes a second metal segment that comprises a second metal material that is different from the first metal material. The second metal segment is laterally between the pair of first metal segments.

Abstract: An OLED display panel may include a substrate, an OLED light emitter on the substrate and configured to emit light, and a visible light sensor on the substrate and configured to detect at least a portion of the emitted light based on reflection of the portion of the emitted light from a recognition target. The visible light sensor is in a non-light emitting region adjacent to the OLED light emitter so as to be horizontally aligned with the OLED light emitter in a horizontal direction extending parallel to an upper surface of the substrate, or between the substrate and a non-light emitting region adjacent to the OLED light emitter such that the visible light sensor is vertically aligned with the non-light emitting region in a vertical direction extending perpendicular to the upper surface of the substrate.