Abstract: A system includes a measuring device, a processing device and a signal generating device. The measuring device is configured to measure a voltage difference between a first node and a second node. The processing device is coupled between the first node and the second node. The signal generating device is configured to provide a first clock signal to the processing device to adjust the voltage difference, configured to generate the first clock signal according to a first enable signal and a second clock signal, and configured to align an edge of the first enable signal with an edge of the second clock signal. A method and a device are also disclosed herein.

Abstract: A method includes forming a static random access memory (SRAM) array comprising a plurality of SRAM cells, at least one of the SRAM cells comprising first and second pull-up transistors, first and second pull-down transistors, and first and second pass-gate transistors; forming a first front-side metal layer above the SRAM array, the first front-side metal layer comprising a first power supply voltage line and a bit-line, the first power supply voltage line electrically coupled to the first and second pull-up transistors, and the bit-line electrically coupled to the first pass-gate transistor; forming a back-side butt contact extending from a back-side of a gate structure of the first pull-up transistor to a back-side of a source/drain region of the second pull-up transistor from a cross sectional view.

Abstract: In a method of manufacturing a semiconductor device, a fin structure is formed over a substrate. The fin structure is sculpted to have a plurality of non-etched portions and a plurality of etched portions having a narrower width than the plurality of non-etched portions. The sculpted fin structure is oxidized so that a plurality of nanowires are formed in the plurality of non-etched portions, respectively, and the plurality of etched portions are oxidized to form oxides. The plurality of nanowires are released by removing the oxides.

Abstract: In a method of manufacturing a semiconductor device, a fin structure having a channel region protruding from an isolation insulating layer disposed over a semiconductor substrate is formed, a cleaning operation is performed, and an epitaxial semiconductor layer is formed over the channel region. The cleaning operation and the forming the epitaxial semiconductor layer are performed in a same chamber without breaking vacuum.

Abstract: A semiconductor device includes a gate electrode, a gate insulating layer, an active layer, a source electrode and a drain electrode. The gate insulating layer is disposed between the gate electrode and the active layer, the source electrode and the drain electrode are arranged on one side of the gate insulating layer, wherein the gate insulating layer includes multilayer oxide films stacked on each other and at least one interface layer between the multilayer oxide films, and the material of the at least one interface layer is different from the material of the oxide films.

Abstract: The present disclosure includes a voltage provision circuit. In one aspect of the present disclosure, a voltage provision circuit is disclosed. The voltage provision circuit includes a first NMOS transistor gated with a first control signal and sourced with a ground voltage. The voltage provision circuit includes a second NMOS transistor gated with a second control signal complementary to the first control signal and sourced with the ground voltage. The voltage provision circuit includes a first PMOS transistor sourced with a first supply voltage. The voltage provision circuit includes a second PMOS transistor sourced with the first supply voltage. The voltage provision circuit includes a voltage modulation circuit, coupled between the first to second PMOS transistors and the first to second NMOS transistors, that is configured to provide a first intermediate signal based on the first and second control signals.

Abstract: A semiconductor device includes a gate structure disposed over a channel region and a source/drain region. The gate structure includes a gate dielectric layer over the channel region, one or more work function adjustment material layers over the gate dielectric layer, and a metal gate electrode layer over the one or more work function adjustment material layers. The one or more work function adjustment layers includes an aluminum containing layer, and a diffusion barrier layer is disposed at at least one of a bottom portion and a top portion of the aluminum containing layer. The diffusion barrier layer is one or more of a Ti-rich layer, a Ti-doped layer, a Ta-rich layer, a Ta-doped layer and a Si-doped layer.

Abstract: A gallium nitride-on-silicon structure is disclosed in which the two-dimensional electron gas (2DEG) layer is a discontinuous layer that includes at least two 2DEG segments. Each 2DEG segment is separated from another 2DEG segment by a gap. The 2DEG layer can be depleted by a p-doped gallium nitride layer that is disposed over a portion of an aluminum gallium nitride layer. Additionally or alternatively, a trench may be formed in the structure through the 2DEG layer to produce a gap in the 2DEG layer. An electrical component is positioned over at least a portion of a gap.

Abstract: A semiconductor device includes source and drain regions, a channel region between the source and drain regions, and a gate structure over the channel region. The gate structure includes a gate dielectric over the channel region, a work function metal layer over the gate dielectric and comprising iodine, and a fill metal over the work function metal layer.

Abstract: A hot spot defect detecting method and a hot spot defect detecting system are provided. In the method, hot spots are extracted from a design of a semiconductor product to define a hot spot map comprising hot spot groups, wherein local patterns in a same context of the design yielding a same image content are defined as a same hot spot group. During runtime, defect images obtained by an inspection tool performing hot scans on a wafer manufactured with the design are acquired and the hot spot map is aligned to each defect image to locate the hot spot groups. The hot spot defects in each defect image are detected by dynamically mapping the hot spot groups located in each defect image to a plurality of threshold regions and respectively performing automatic thresholding on pixel values of the hot spots of each hot spot group in the corresponding threshold region.

Abstract: The present disclosure is directed to methods for the fabrication of buried layers in gate-all-around (GAA) transistor structures to suppress junction leakage. In some embodiments, the method includes forming a doped epitaxial layer on a substrate, forming a stack of alternating first and second nano-sheet layers on the epitaxial layer, and patterning the stack and the epitaxial layer to form a fin structure. The method includes forming a sacrificial gate structure on the fin structure, removing portions of the fin structure not covered by the sacrificial gate structure, and etching portions of the first nano-sheet layers. Additionally, the method includes forming spacer structures on the etched portions of the first nano-sheet layers and forming source/drain (S/D) epitaxial structures on the epitaxial layer abutting the second nano-sheet layers.

Abstract: A semiconductor device includes a field effect transistor (FET). The FET includes a first channel, a first source and a first drain; a second channel, a second source and a second drain; and a gate structure disposed over the first and second channels. The gate structure includes a gate dielectric layer and a gate electrode layer. The first source includes a first crystal semiconductor layer and the second source includes a second crystal semiconductor layer. The first source and the second source are connected by an alloy layer made of one or more Group IV element and one or more transition metal elements. The first crystal semiconductor layer is not in direct contact with the second crystal semiconductor layer.

Abstract: A device includes first and second gate structures respectively extending across the first and second fins, and a gate isolation plug between a longitudinal end of the first gate structure and a longitudinal end of the second gate structure. The gate isolation plug comprises a first dielectric layer and a second dielectric layer over the first dielectric layer. The first dielectric layer has an upper portion and a lower portion below the upper portion. The upper portion has a thickness smaller than a thickness of the lower portion of the first dielectric layer.

Abstract: The present disclosure is directed to method for the fabrication of spacer structures between source/drain (S/D) epitaxial structures and metal gate structures in nanostructure transistors. The method includes forming a fin structure with alternating first and second nanostructure elements on a substrate. The method also includes etching edge portions of the first nanostructure elements in the fin structure to form cavities. Further, depositing a spacer material on the fin structure to fill the cavities and removing a portion of the spacer material in the cavities to form an opening in the spacer material. In addition, the method includes forming S/D epitaxial structures on the substrate to abut the fin structure and the spacer material so that sidewall portions of the S/D epitaxial structures seal the opening in the spacer material to form an air gap in the spacer material.

Abstract: A manufacturing process is described to evaluate and select raw semiconductor wafers in preparation for epitaxial layer formation. The manufacturing process first produces a single crystal ingot during which a seed pulling velocity and temperature gradient are closely controlled. The resulting ingot is vacancy-rich with relatively few self-interstitial defects. Selected wafers can advance to a high-temperature nitridation annealing operation that further reduces the number of interstitials while increasing the vacancies. Substrates characterized by a high vacancy density can then be used to optimize an epitaxial layer deposition process.

Abstract: A semiconductor device and a method for manufacturing an interconnecting metal layer thereof are provided. The semiconductor device includes a gate layer, a dielectric layer, an insulating layer, an epitaxial layer, and a sidewall liner. The dielectric layer is disposed on one side of the gate layer, the insulating layer is disposed on another side of the gate layer, the epitaxial layer is located on the insulating layer, and the sidewall liner penetrates the dielectric layer and the gate layer, and one end of the sidewall liner is connected to the epitaxial layer. The sidewall liner is converted from a high-k material to a low-k material by hydrogen and oxygen plasma treatments.

Abstract: An interconnect structure is provided. The interconnect structure includes a transistor on a substrate, a first dielectric layer over the transistor, a first metal line through the first dielectric layer, a second dielectric layer over the first dielectric layer, and a via through the second dielectric layer and on the first metal line. A first side surface of the first dielectric layer includes a first portion in direct contact with the first metal line and a second portion in direct contact with the via, and the first portion of the first side surface of the first dielectric layer is aligned with the second portion of the first side surface of the first dielectric layer.

Abstract: A semiconductor device includes a substrate, an interconnect structure, and conductive vias. The substrate has a first side, a second side and a sidewall connecting the first side and the second side, wherein the sidewall includes a first planar sidewall of a first portion of the substrate, a second planar sidewall of a second portion of the substrate and a curved sidewall of a third portion of the substrate, where the first planar sidewall is connected to the second planar sidewall through the curved sidewall. The interconnect structure is located on the first side of the substrate, where a sidewall of the interconnect structure is offset from the second planar sidewall. The conductive vias are located on the interconnect structure, where the interconnect structure is located between the conductive vias and the substrate.

Abstract: A semiconductor device and a method of operating the semiconductor device are disclosed. In one aspect, the semiconductor device includes a memory cell connected to a bit line, and a biasing circuit configured to output a first bias voltage and a second bias voltage, the first bias voltage generated based on a threshold voltage of a p-type transistor, and the second bias voltage generated based on a threshold voltage of an n-type transistor. The semiconductor device includes a step-down circuit connected to the bit line and configured to receive the first and second bias voltages, the step-down circuit configured to output an output voltage to charge the bit line based on the first and second bias voltages.

Abstract: Structures with doping free connections and methods of fabrication are provided. An exemplary structure includes a substrate; a first region of a first conductivity type formed in the substrate; an overlying layer located over the substrate; a well region of a second conductivity type formed in the overlying layer; a conductive plug laterally adjacent to the well region and extending through the overlying layer to electrically contact with the first region; and a passivation layer located between the conductive plug and the well region.