Abstract: A method is provided for fabricating a transistor. The method includes providing a semiconductor substrate, and forming a metal layer on the semiconductor substrate. The method also includes forming a silicon layer having at least one layer of graphene-like silicon on the metal layer, and forming a metal oxide layer by oxidizing a portion of the metal layer underneath the silicon layer. Further, the method includes forming a source region and a drain region connecting with the silicon layer.

Abstract: Various embodiments provide methods and systems for making and/or cleaning semiconductor devices. In one embodiment, a semiconductor device can be formed including a metal layer and a photoresist polymer. During formation, the semiconductor device can be cleaned in a cleaning chamber by a first cleaning solution provided from a solution supply device. After this cleaning process, a second cleaning solution containing metal ions and/or polymer residues can be produced and processed in a solution processing device to at least partially remove the metal ions and/or polymer residues to produce a third cleaning solution for re-use. In an exemplary fabrication or cleaning system, the solution processing device may be configured connecting to either an inlet or an outlet of the cleaning chamber. After cleaning, the semiconductor device can be processed to include a metal plug or an interconnect wiring.

Abstract: A method is provided for fabricating small pitch patterns. The method includes providing a semiconductor substrate, and forming a target material layer having a first region and a second region on the semiconductor substrate. The method also includes forming a plurality of discrete first sacrificial layers on the first region of the target material layer and a plurality of discrete second sacrificial layers on the second region of the target material layer, and forming first sidewall spacers on both sides of the discrete first sacrificial layers and the discrete second sacrificial layers. Further, the method includes removing the first sacrificial layers and the second sacrificial layers, and forming second sidewall spacers. Further, the method also includes forming discrete repeating patterns in the first region of the target material layer and a continuous pattern in the second region of the target material layer.

Abstract: Exemplary embodiments provide transistors and methods for forming the transistors. An exemplary CMOS transistor can be formed by epitaxially forming a first stress layer in/on a semiconductor substrate having a first region including a first gate structure and a second region including a second gate structure. A barrier layer can be formed to cover the second region and to expose the first region. The barrier layer can be used as a mask to remove a portion of the first stress layer from the first region. A second stress layer can be formed in a groove formed in the semiconductor substrate on sides of the first gate structure in the first region. The fabrication method can be simplified and the formed CMOS transistors can have high carrier mobility.

Abstract: Various embodiments provide semiconductor structures and their fabrication methods. An SRAM memory cell can include at least one semiconductor structure, and an SRAM memory can include at least one SRAM memory cell. An exemplary semiconductor structure can include at least two adjacent transistors formed on a semiconductor substrate. An opening can be formed and surrounded by gates of the two adjacent transistors and a doped region formed between the gates of the two adjacent transistors. A conductive layer can be formed to at least partially cover a bottom and a sidewall of the opening to electrically connect a gate of one transistor with the doped region of the other transistor of the two adjacent transistors.

Abstract: A method for forming metal gates is provided. In the method, a substrate with a first region and a second region is provided. Dummy gate structures and an ILD layer is formed on the substrate. Dummy gates of the dummy gate structures are removed to form openings respectively within the two regions. Work function layers are respectively formed to overlay the openings. A metal layer is formed on the work function layers and then a CMP process is performed until the ILD layer is exposed, thereby forming the metal gates within the two regions at the same time. Only one CMP process is performed to the metal layer, so that over polishing of the ILD layer may be reduced and thickness of metal gates may be more accurately controlled.

Abstract: Various embodiments provide transistors and their fabrication methods. An exemplary method for forming a transistor includes removing a dummy gate to form a trench over a semiconductor substrate. A high-k dielectric layer can be conformally formed on surface of the trench and then be fluorinated to form a fluorinated high-k dielectric layer. A functional layer can be formed on the fluorinated high-k dielectric layer and a metal layer can be formed on the functional layer to fill the trench with the metal layer. Due to fluorination of the high-k dielectric layer, negative bias temperature instability of the formed transistor can be reduced and oxygen vacancies can be passivated to reduce positive bias temperature instability of the transistor.

Abstract: Semiconductor devices having a buried layer and methods for forming the same are disclosed. In an exemplary method, a hard mask layer can be provided on a semiconductor substrate. The hard mask layer can have a plurality of through-openings. A plurality of deep trenches can be formed in the semiconductor substrate using the hard mask layer as a mask. A bottom of each of the plurality of deep trenches in the semiconductor substrate can be doped to form a plurality of heavily-doped regions. One or more of the plurality of heavily-doped regions can be connected to form the buried layer in the semiconductor substrate. There is thus no need to use an epitaxial process to form active regions. In addition, lateral isolation structures can be simultaneously formed in the semiconductor substrate.

Abstract: A method is provided for fabricating a semiconductor structure. The method includes providing a semiconductor substrate, and forming a shallow trench isolation structure in the semiconductor substrate. The method also includes forming a plurality of parallel gate structures on the semiconductor substrate surrounded by the shallow trench isolation structure. Further, the method includes forming a plurality of first trenches in the semiconductor substrate at least one side of the gate structures proximity to the shallow trench isolation structure, and forming a first silicon germanium layer with a first germanium concentration in each of the first trenches. Further the method also includes forming a plurality second trenches in semiconductor substrate at least one side of the gate structures farther from the shallow trench isolation structure, and forming a second silicon germanium layer with a second germanium concentration greater than the first germanium concentration in each of the second trenches.

Abstract: Various embodiments provide methods and systems for making and/or cleaning semiconductor devices. In one embodiment, a semiconductor device can be formed including a metal layer and a photoresist polymer. During formation, the semiconductor device can be cleaned in a cleaning chamber by a first cleaning solution provided from a solution supply device. After this cleaning process, a second cleaning solution containing metal ions and/or polymer residues can be produced and processed in a solution processing device to at least partially remove the metal ions and/or polymer residues to produce a third cleaning solution for re-use. In an exemplary fabrication or cleaning system, the solution processing device may be configured connecting to either an inlet or an outlet of the cleaning chamber. After cleaning, the semiconductor device can be processed to include a metal plug or an interconnect wiring.

Abstract: A method is provided for fabricating a semiconductor structure. The method includes providing a semiconductor substrate, and forming a shallow trench isolation structure in the semiconductor substrate. The method also includes forming a plurality of parallel gate structures on the semiconductor substrate surrounded by the shallow trench isolation structure. Further, the method includes forming a plurality of first trenches in the semiconductor substrate at least one side of the gate structures proximity to the shallow trench isolation structure, and forming a first silicon germanium layer with a first germanium concentration in each of the first trenches. Further the method also includes forming a plurality second trenches in semiconductor substrate at least one side of the gate structures farther from the shallow trench isolation structure, and forming a second silicon germanium layer with a second germanium concentration greater than the first germanium concentration in each of the second trenches.

Abstract: An exposure method and an exposure device are provided. An exemplary exposure device includes a stage, a first clamp holder, a second clamp holder, an optical projection unit, a first alignment detection unit, and/or a second alignment detection unit. The stage includes a first region and a second region. The first clamp holder is located in the first region and adapted for holding a first substrate, and the second clamp holder is located in the second region and adapted for holding a second substrate. The optical projection unit is located above the stage and adapted for exposure of the first substrate or the second substrate. The first alignment detection unit is adapted for detecting alignment marks of the first substrate. The second alignment detection unit is adapted for detecting alignment marks of the second substrate. The exposure device can accurately position the stage and improve production yield.

Abstract: Various embodiments provide transistors and fabrication methods. An exemplary transistor can include a silicon nitride layer disposed between a gate dielectric layer and a gate electrode layer. The silicon nitride layer can have a first surface in contact with the gate dielectric layer and a second surface in contact with the gate electrode layer. The second surface can include silicon atoms having a concentration higher than the first surface. A sidewall spacer can be formed on the semiconductor substrate along sidewalls of each of the gate electrode layer, the silicon nitride layer, and the gate dielectric layer. The disclosed transistor can have a reduced turn-on voltage with reduced power consumption.

Abstract: A method is provided for fabricating a through silicon via packaging structure. The method includes providing a first type substrate, and forming a second type substrate deferent from the first type substrate on the first type substrate. The method also includes forming a semiconductor device on a first surface of the second type substrate, and forming an interlayer dielectric layer on the first surface of the second type substrate. Further, the method includes forming a metal interconnection structure in the interlayer dielectric layer, and forming a through silicon via structure perforating the second type substrate and electrically connecting with the metal interconnection structure. Further, the method also includes removing the first type substrate using a gas etching process or a wet etching process to expose a second surface of the second type substrate and a bottom surface of the through silicon via structure.

Abstract: A method is provided for fabricating a PMOS transistor. The method includes providing a semiconductor substrate, and forming a dummy gate structure at least having a dummy gate, a high-K dielectric layer, and a sidewall spacer surrounding the high-K dielectric layer and the dummy gate on the semiconductor substrate. The method also includes forming a source region and a drain region in the semiconductor substrate at both sides of the dummy gate structure by an ion implantation process, and performing a first annealing process to enhance the ion diffusion. Further, the method includes forming an interlayer dielectric layer leveling with the surface of the dummy gate, and forming a trench by removing the dummy gate. Further, the method also includes performing a second annealing process, and forming a metal gate in the trench.

Abstract: A method is provided for fabricating a High-K layer. The method includes providing a substrate, applying a first precursor gas on the substrate such that the substrate absorbs first precursor gas molecules in a chemical absorption process, and removing the unabsorbed first precursor gas using a first inert gas. The method also includes applying a second precursor gas on the substrate, and forming a first thin film on the substrate as a reaction product of the second precursor gas and the absorbed first precursor gas molecules. Further, the method includes removing unreacted second precursor gas and byproducts using a second inert gas, and forming a high-K layer on the substrate by forming a plurality of the first thin films layer-by-layer.

Abstract: A method is provided for fabricating a CMOS device. The method includes providing a semiconductor substrate having a first active region and a second active region. The method also includes forming a first trench on the first active region using a first barrier layer and a second substitute gate electrode layer to protect a gate region on the second active region, followed by forming a first work function layer and a first metal gate in the first trench. Further, the method includes forming a second trench on the second active region using a second barrier layer to protect the first metal gate structure, followed by forming a second work function layer and a second metal gate in the second trench.

Abstract: A method is provided for fabricating an integrated semiconductor device. The method includes providing a semiconductor substrate having a first active region, a second active region and a plurality of isolation regions; forming a first gate dielectric layer on one surface of the semiconductor substrate; and forming a plurality of substituted gate electrodes, a layer of interlayer dielectric and sources/drains. The method also includes forming a first trench and a second trench; and covering the first gate dielectric layer on the bottom of the first trench. Further, the method includes removing the first dielectric layer on the bottom of the second trench; subsequently forming a second gate dielectric layer on the bottom of the second trench; and forming metal gates by filling the first trench and second trench using a high-K dielectric layer, followed by completely filling the first trench and the second trench using a gate metal layer.

Abstract: Various embodiments provide voltage regulator circuitry and devices. An exemplary voltage regulator circuitry can include a current comparing unit configured to convert an output voltage from a charge pump to a current and to compare the current with at least two different reference currents to generate a comparison result. A logic controller can be configured to generate a clock frequency adjustment signal based on the comparison result. A programmable clock unit can be configured to adjust a frequency of a clock signal according to the clock frequency adjustment signal to send the clock signal to the charge pump. Accordingly, the disclosed voltage regulator device can have reduced power consumption and improved reliability.

Abstract: Various embodiments provide an MOS transistor, a formation method thereof, and an SRAM memory cell circuit. An exemplary MOS transistor can include a channel region including an asymmetric stressing layer having a stress gradually varied from a compressive stress to a tensile stress or from a tensile stress to a compressive stress from a first end of the channel region adjacent to a source region to a second end of the channel region adjacent to a drain region. The MOS transistor can be used as a transfer transistor in an SRAM memory cell circuit to increase a source-drain saturation current in a write operation and to reduce a source-drain saturation current in a read operation. Read and write margins of the SRAM can be increased.