Abstract: It is an object of an embodiment of the present invention to reduce leakage current between a source and a drain in a transistor including an oxide semiconductor. As a first gate film in contact with a gate insulating film, a compound conductor which includes indium and nitrogen and whose band gap is less than 2.8 eV is used. Since this compound conductor has a work function of greater than or equal to 5 eV, preferably greater than or equal to 5.5 eV, the electron concentration in an oxide semiconductor film can be maintained extremely low. As a result, the leakage current between the source and the drain is reduced.

Abstract: A manufacturing method for a metal gate includes providing a substrate having at least a semiconductor device with a conductivity type formed thereon, forming a gate trench in the semiconductor device, forming a work function metal layer having the conductivity type and an intrinsic work function corresponding to the conductivity type in the gate trench, and performing an ion implantation to adjust the intrinsic work function of the work function metal layer to a target work function.

Abstract: Forming conformal platinum-zinc films for semiconductor devices is described. In one example, a conformal film is formed by heating a substrate in a reaction chamber, exposing a desired region of the substrate to a precursor that contains platinum, purging excess precursor from the chamber, exposing the desired region of the substrate to a co-reactant containing zinc to cause a reaction between the precursor and the co-reactant to form a platinum zinc film on the desired region, and purging the chamber of excess reaction by-products.

Abstract: Embodiments of the present invention provide the ability to fabricate devices having similar physical dimensions, yet with different operating characteristics due to the different effective channel lengths. The effective channel length is controlled by forming an abrupt junction at the boundary of the gate and at least one source or drain. The abrupt junction impacts the diffusion during an anneal process, which in turn controls the effective channel length, allowing physically similar devices on the same chip to have different operating characteristics.

Abstract: A trenched power semiconductor structure with reduced gate impedance and a fabrication method thereof is provided. The trenched power semiconductor structure has a silicon base, a gate trench, a gate oxide layer, and a gate polysilicon structure. The gate trench is formed in the silicon base and extended to an upper surface of the silicon base. The gate oxide layer is formed at least on the inner surface of the gate trench. The gate polysilicon structure is formed in the gate trench with a protruding portion extended form the upper surface of the semiconductor substrate upward. A concave is formed on a sidewall of the protruding portion to expose the upper surface of the silicon base adjacent to the gate trench.

Abstract: According to one disclosed embodiment, a method for fabricating an integrated resistor in a semiconductor die includes forming a high-k dielectric over a substrate and a metal layer over the high-k dielectric, where the metal layer forms a resistive element of the integrated resistor. The method further includes forming an un-doped polysilicon layer over the metal layer, where a portion of the un-doped polysilicon layer can be selectively doped and used to form a conductive path to the resistive element of the integrated resistor. In one embodiment, the metal layer comprises a gate metal. In one embodiment, the integrated resistor is formed substantially concurrently with one or more transistors without requiring additional fabrication process steps. One disclosed embodiment is an integrated resistor formed according to the disclosed method.

Abstract: A semiconductor device includes a semiconductor substrate, a p-channel MIS transistor formed on the substrate, the p-channel transistor having a first gate dielectric formed on the substrate and a first gate electrode layer formed on the first dielectric, and an n-channel MIS transistor formed on the substrate, the n-channel transistor having a second gate dielectric formed on the substrate and a second gate electrode layer formed on the second dielectric. A bottom layer of the first gate electrode layer in contact with the first gate dielectric and a bottom layer of the second gate electrode layer in contact with the second gate dielectric have the same orientation and the same composition including Ta and C, and a mole ratio of Ta to a total of C and Ta, (Ta/(Ta+C)), is larger than 0.5.

Abstract: A substrate diode for an SOI device is formed in accordance with an appropriately designed manufacturing flow, wherein transistor performance enhancing mechanisms may be implemented substantially without affecting the diode characteristics. In one aspect, respective openings for the substrate diode may be formed after the formation of a corresponding sidewall spacer structure used for defining the drain and source regions, thereby obtaining a significant lateral distribution of the dopants in the diode areas, which may therefore provide sufficient process margins during a subsequent silicidation sequence on the basis of a removal of the spacers in the transistor devices. In a further aspect, in addition to or alternatively, an offset spacer may be formed substantially without affecting the configuration of respective transistor devices.

Abstract: A method for forming a semiconductor structure includes providing a semiconductor substrate; forming a gate dielectric layer on the semiconductor substrate; forming a metal-containing layer on the gate dielectric; and forming a composite layer over the metal-containing layer. The step of forming the composite layer includes forming an un-doped silicon layer substantially free from p-type and n-type impurities; and forming a silicon layer adjoining the un-doped silicon layer. The step of forming the silicon layer comprises in-situ doping a first impurity. (or need to be change to: forming a silicon layer first & then forming un-doped silicon layer) The method further includes performing an annealing to diffuse the first impurity in the silicon layer into the un-doped silicon layer.

Abstract: Provided is a highly reliable semiconductor device equipped with a plurality of semiconductor elements having desired properties, respectively; and a manufacturing method facilitating the manufacture of the semiconductor device. The semiconductor device is manufactured by forming a gate-electrode metal film having a thickness of from 3 to 30 nm over the entire upper surface of a gate insulating film; forming an n-side cap layer having a thickness of 10 nm or less over the entire upper surface of a portion of the gate-electrode metal film belonging to an nFET region by using a material different from that of the gate-electrode metal film; and carrying out heat treatment over the n-side cap layer to diffuse the material of the n-side cap layer into the gate-electrode metal film immediately below the n-side cap layer and react them to form an n-side gate-electrode metal film in a nFET region. A poly-Si layer is then deposited, followed by gate electrode processing.

Abstract: Structure and method of improving the performance of metal gate devices by depositing an in-situ silicon (Si) cap are disclosed. A wafer including a substrate and a dielectric layer is heated through a degas process, and then cooled to approximately room temperature. A metal layer is then deposited, and then an in-situ Si cap is deposited thereon. The Si cap is deposited without vacuum break, i.e., in the same mainframe or in the same chamber, as the heating, cooling and metal deposition processes. As such, the amount of oxygen available for interlayer oxide regrowth during subsequent processing is reduced as well as the amount oxygen trapped in the metal gate.

Abstract: A semiconductor device in which the diffusion of copper from a wire is prevented and a method for fabricating such a semiconductor device. For example, a via groove and a wire groove are formed in a multilayer structure including a UDC diffusion barrier film, a porous silica film, a middle UDC stopper film, a porous silica film, a UDC diffusion barrier film, and the like, and the surfaces the UDC diffusion barrier film, the middle UDC stopper film, and the UDC diffusion barrier film that get exposed in the via groove and the wire groove are irradiated with hydrogen plasma, thereby making the surface of each exposed SiC film silicon-rich. After the plasma irradiation, a Ta film is formed in the via groove and the wire groove and copper is embedded in these grooves. By making the surface of each SiC film which is to touch the Ta film silicon-rich in advance, the crystal structure of the Ta film can be controlled so that copper cannot pierce through the Ta film. This prevents copper from diffusing from a wire.

Abstract: A method for manufacturing a CMOS device having dual metal gate includes providing a substrate having at least two transistors of different conductive types and a dielectric layer covering the two transistors, planarizing the dielectric layer to expose gate conductive layers of the two transistors, forming a patterned blocking layer exposing one of the conductive type transistor, performing a first etching process to remove a portion of a gate of the conductive type transistor, reforming a metal gate, removing the patterned blocking layer, performing a second etching process to remove a portion of a gate of the other conductive type transistor, and reforming a metal gate.

Abstract: A forming method of an electrode includes the steps of providing an electrode material on a conductive part; exposing the electrode material at a temperature equal to or higher than a melting point of the electrode material in an oxidizing atmosphere; and exposing the melted electrode material, in a reducing atmosphere, at a temperature equal to or higher than the melting point of the electrode material and lower than the temperature at which the electrode material is exposed in the oxidizing atmosphere.

Abstract: A substrate diode for an SOI device is formed in accordance with an appropriately designed manufacturing flow, wherein transistor performance enhancing mechanisms may be implemented substantially without affecting the diode characteristics. In one aspect, respective openings for the substrate diode may be formed after the formation of a corresponding sidewall spacer structure used for defining the drain and source regions, thereby obtaining a significant lateral distribution of the dopants in the diode areas, which may therefore provide sufficient process margins during a subsequent silicidation sequence on the basis of a removal of the spacers in the transistor devices. In a further aspect, in addition to or alternatively, an offset spacer may be formed substantially without affecting the configuration of respective transistor devices.

Abstract: Disclosed in a method of forming a copper wiring in a semiconductor device. A copper layer buries a damascene pattern in which an interlayer insulating film of a low dielectric constant. The copper layer is polished by means of a chemical mechanical polishing process to form a copper wiring within a damascene pattern. At this time, the chemical mechanical polishing process is overly performed so that the top surface of the copper wiring is concaved and is lower than the surface of the interlayer insulating film of the low dielectric constant neighboring it. Furthermore, an annealing process is performed so that the top surface of the copper wiring is changed from the concaved shape to a convex shape while stabilizing the copper wiring. A copper anti-diffusion insulating film is then formed on the entire structure including the top surface of the copper wiring having the convex shape.

Abstract: The present invention provides a method for purifying ruthenium sources to obtain high purity ruthenium metal and form a ruthenium metal pattern on a semiconductor substrate without the need for high temperature processing or a complex series of wet processes. A gas stream including ozone (O3) is brought into contact with a ruthenium source in one or more reaction vessels to form ruthenium tetraoxide (RuO4), a compound that is a gas at the reaction conditions. The ruthenium tetraoxide, along with unreacted ozone and the remainder of the gas stream is then fed into a collection vessel where the gaseous ruthenium tetraoxide is reduced to form a ruthenium dioxide (RuO2) layer on a semiconductor substrate. The deposited ruthenium dioxide is then reduced, preferably with hydrogen, to produce highly pure ruthenium metal that may be, in turn, patterned and dry etched using ozone as an etchant gas.