Abstract: A method for forming a carbon-containing silicon nitride layer with superior uniformity by low pressure chemical vapor deposition (LPCVD) using disilane, ammonia and at least one carbon-source precursor as reactant gases is provided.

Abstract: A transistor of a pixel cell for use in a CMOS imager with a low threshold voltage of about 0.3 V to less than about 0.7 V is disclosed. The transistor is provided with high dosage source and drain regions around the gate electrode and with the halo implanted regions and/or the lightly doped LDD regions and/or the enhancement implanted regions omitted from at least one side of the gate electrode. The low threshold transistor is electrically connected to a high voltage transistor with a high threshold voltage of about 0.7 V.

Abstract: A process and structure for a metal interconnect includes providing a substrate with a first electric conductor, forming a first dielectric layer and a first patterned hard mask, using the first patterned hard mask to form a first opening and a second electric conductor, forming a second dielectric layer and a second patterned hard mask, using the second patterned hard mask as an etching mask and using a first patterned hard mask as an etch stop layer to form a second opening and a third electric conductor.

Abstract: A Metal Oxide Semiconductor device includes a semiconductor substrate; a gate electrode formed on the surface of the substrate, having an offset spacer on each side; source/drain electrodes in the substrate having lightly doped regions respectively; metal silicide located on the gate electrode and the source/drain electrodes; and first impurity ions and second impurity ions in the lightly doped regions. A method for manufacturing a Metal Oxide Semiconductor device includes forming a gate electrode on a semiconductor substrate; implanting first impurity ions and second impurity ions to form lightly doped regions; depositing a dielectric layer and etching the dielectric layer to form offset spacers; implanting the first impurity ions to form the source/drain electrodes; forming metal silicide on the surfaces of the gate electrode and the source/drain regions. This invention can effectively prevent metal nickel diffusion into the lightly doped regions.

Abstract: A method of manufacturing a semiconductor device including at least one step of: forming a transistor on and/or over a semiconductor substrate; forming silicide on and/or over a gate electrode and a source/drain region of the transistor; removing an uppermost oxide film from a spacer of the transistor; and forming a contact stop layer on and/or over the entire surface of the substrate including the gate electrode.

Abstract: A semiconductor lateral voltage-sustaining region and devices based thereupon. The voltage-sustaining region is made by using the Metal-Insulator-Semiconductor capacitance formed by terrace field plate to emit or to absorb electric flux on the semiconductor surface, so that the effective electric flux density emitted from the semiconductor surface to the substrate approaches approximately the optimum distribution, and a highest breakdown voltage can be achieved within a smallest distance on the surface. The field plates can be either floating ones, or connected to floating field limiting rings. Coupling capacitance between different plates can also be used to change the flux distribution.

Abstract: The present invention provides a method of forming a interconnect barrier layer 100. In the method, physical vapor deposition of barrier material 200 is performed within an opening 140 located in a dielectric layer 135 of a substrate 110. RF plasma etching of the barrier material 200 that is deposited in the opening 140 occurs simultaneously with conducting the physical vapor deposition of the barrier material 200.

Abstract: In one embodiment, a method of fabricating an integrated circuit includes the steps of: (i) forming composite spacers on sidewalls of a transistor gate, each of the composite spacers comprising a first liner having a stepped portion and a disposable spacer material over the stepped portion; (ii) forming a source/drain region by performing ion implantation through a portion of the first liner over the source/drain region; (iii) replacing the disposable spacer material with a second liner formed over the first liner after forming the source/drain region; (iv) forming a pre-metal dielectric over the second liner; and (v) forming a self-aligned contact through the pre-metal dielectric. Among other advantages, the method allows for an increased contact area for a self-aligned contact.

Abstract: A number of minuscule LDD thin film transistors with high precision are arranged on a substrate for use in a liquid crystal display apparatus or other similar devices. The gate electrode is used as a mask at the time of injecting impurities into the semiconductor layer. To realize an LDD structure, the impurities are injected in two installments. The size of the gate electrode is changed in accordance with the length of the LDD regions between the first and second injections. The size of the gate electrode is changed by means of metal oxidation or dry etching. For precision dry etching of the gate electrode, various ideas are put into forming the photo resist.

Abstract: In a high-voltage PMOS transistor having an insulated gate electrode (18), a p-conductive source (15) in an n-conductive well (11), a p-conductive drain (14) in a p-conductive well (12) which is arranged in the n-conductive well, and having a field oxide area (13) between the gate electrode and drain, the depth (A?-B?) of the n-conductive well underneath the drain (14) is less than underneath the source (15), and the depth (A?-B?) of the p-conductive well is greatest underneath the drain (14).

Abstract: The semiconductor device comprises: a semiconductor substrate (N+ substrate 110) containing a first conductivity type impurity implanted therein; a second conductivity type impurity-implanted layer (P+ implanted layer 114) at relatively high concentration, formed on the semiconductor substrate (N+ substrate 110); a second conductivity type impurity epitaxial layer (P? epitaxial layer 111) at relatively low concentration, formed on the second conductivity type impurity-implanted layer (P+ implanted layer 114); and a field effect transistor 100 (N-channel type lateral MOSFET 100) composed of a pair of impurity diffusion regions (N+ source diffusion layer 115 and N? drain layer 116) provided in the second conductivity type impurity epitaxial layer (P? epitaxial layer 111) and a gate electrode 117 provided over a region sandwiched with the pair of impurity diffusion regions (N+ source diffusion layer 115 and N? drain layer 116).

Abstract: The present disclosure provides a system for removing a spacer, such as associated with a processing operation using a lightly doped drain (LDD) region. In one example, the system includes means for creating a spacer, means for implanting a first relatively heavily doped region with the spacer in place, one or more chambers for removing the spacer, and means for implanting the LDD region with the spacer removed. The one or more chambers may be configured for applying a first dry removal process to remove the layer on the spacer utilizing a fluorine-contained plasma and applying a second wet etch process to remove the spacer.

Abstract: A preferred embodiment of the invention provides a semiconductor fabrication method. An embodiment comprises forming a MOS device having sidewall spacers. A highly stressed layer is deposited over the device. The stress is selectively adjusted in that portion of the layer over the gate electrode and the sidewall spacers. Preferably, the stress layer over the gate electrode and over the sidewall spacers is adjusted from a first stress to a second stress, wherein the first stress is one of tensile and compressive, and the second stress is the other of tensile and compressive. Preferred embodiments selectively induce a suitable stress within PMOS and NMOS channel regions for improving their respective carrier mobility. Still other embodiments of the invention comprise a field effect transistor (FET) having a overlying stressed layer, the stressed layer being comprised of different stress regions.

Abstract: A high voltage device with retrograde well is disclosed. The device comprises a substrate, a gate region formed on the substrate, and a retrograde well placed in the substrate next to the gate region, wherein the retrograde well reduces a dopant concentration on the surface of the substrate, thereby minimizing damages to the gate region.

Abstract: A method of forming a semiconductor device, including providing a substrate having a first insulative layer on a surface of the substrate, and a device layer on a surface of the first insulative layer, forming a spacer around the first insulative layer and the device layer, removing a portion of the substrate adjacent to the first insulative layer in a first region and a non-adjacent second region of the substrate, such that an opening is formed in the first and second regions of the substrate, leaving the substrate adjacent to the first insulative layer in a third region of the substrate, filling the opening within the first and second regions of the substrate, planarizing a surface of the device, and forming a device within the device layer, such that diffusion regions of the device are formed within the device layer above the first and second regions of the substrate, and a channel region of the device is formed above the third region of the substrate.

Abstract: A Co silicide layer having a low resistance and a small junction leakage current is formed on the surface of the gate electrode, source and drain of MOSFETs by silicidizing a Co film deposited on a main plane of a wafer by sputtering using a high purity Co target having a Co purity of at least 99.99% and Fe and Ni contents of not greater than 10 ppm, preferably having a Co purity of 99.999%.

Abstract: A transistor of a pixel cell for use in a CMOS imager with a low threshold voltage of about 0.3 V to less than about 0.7 V is disclosed. The transistor is provided with high dosage source and drain regions around the gate electrode and with the halo implanted regions and/or the lightly doped LDD regions and/or the enhancement implanted regions omitted from at least one side of the gate electrode. The low threshold transistor is electrically connected to a high voltage transistor with a high threshold voltage of about 0.7 V.

Abstract: A method of fabricating a gate electrode of a semiconductor device is disclosed. A disclosed method comprises growing a silicon epitaxial layer on a silicon substrate; making at least one trench through the epitaxial layer and filling the trench with a first oxide layer; etching the first oxide layer to form reverse spacers in the trench; depositing a second oxide layer and a polysilicon layer over the silicon substrate including the trench and the reverse spacers and forming a gate; implanting ions in the silicon substrate at both sides of the gate to form pocket-well and LDD areas; depositing a nitride layer over the silicon substrate including the gate and etching the nitride layer to form spacers; implanting ions using the spacers and the gate as a mask to make a source/drain region; and forming a silicide layer on the top of the gate electrode and the silicon epitaxial layer positioned on the source/drain region.

Abstract: A method for forming a transistor including a self aligned metal gate is provided. According to various method embodiments, a high-k gate dielectric is formed on a substrate and a sacrificial carbon gate is formed on the gate dielectric. Sacrificial carbon sidewall spacers are formed adjacent to the sacrificial carbon gate, and source/drain regions for the transistor are formed using the sacrificial carbon sidewall spacers to define the source/drain regions. The sacrificial carbon sidewall spacers are replaced with non-carbon sidewall spacers, and the sacrificial carbon gate is replaced with a desired metal gate material to provide the desired metal gate material on the gate dielectric. Various embodiments form source/drain extensions after removing the carbon sidewall spacers and before replacing with non-carbon sidewall spacers. An etch barrier is used in various embodiments to separate the sacrificial carbon gate from the sacrificial carbon sidewall spacers.

Abstract: A gate electrode is formed over but insulated from a semiconductor body region for each of first and second transistors. A DDD implant is carried out to from DDD source and DDD drain regions in the body region for the first transistor. After the DDD implant, off-set spacers are formed along side-walls of the gate electrode of each of the first and second transistors. After forming the off-set spacers, a LDD implant is carried out to from LDD source and drain regions in the body region for the second transistor. After the LDD implant, main spacers are formed adjacent the off-set spacers of at least the second transistor. After forming the main spacers, a source/drain implant is carried out to form a highly doped region within each of the DDD drain and source regions and the LDD drain and source regions.

Abstract: A method of producing an insulator thin film, for forming a thin film on a substrate by use of the atomic layer deposition process, includes a first step of forming a silicon atomic layer on the substrate and forming an oxygen atomic layer on the silicon atomic layer, and a second step of forming a metal atomic layer on the substrate and forming an oxygen atomic layer on the metal atomic layer, wherein the concentration of the metal atoms in the insulator thin film is controlled by controlling the number of times the first step and the second step are carried out.

Abstract: A semiconductor device is disclosed, which comprises a semiconductor substrate, source/drain regions formed in the semiconductor substrate, a gate insulating film formed on a channel region between the source/drain regions, a gate electrode formed on the gate insulating film, and a sidewall insulating film formed on a sidewall surface of the gate electrode, wherein the gate electrode is made of SiGe, the sidewall insulating film is an insulating film obtained by oxidizing the sidewall surface of the gate electrode, and the sidewall insulating film contains silicon oxide as a main component.

Abstract: A MISFET capable of a high speed operation includes a metal silicide layer in a high concentration region aligned with a gate side wall layer on a self-alignment basis. A MISFET which can be driven at a high voltage includes an LDD portion having a width greater than the width of the side wall layer, a high concentration region in contact with the LDD portion and a metal silicide layer in the high concentration region.

Abstract: An operational withstand voltage of a high voltage MOS transistor is enhanced and a variation in a saturation current Idsat is suppressed. A gate insulation film is formed on a P-type semiconductor substrate. A gate electrode is formed on the gate insulation film. A first low impurity concentration source layer and a first low impurity concentration drain layer are formed by tilt angle ion implantation of double charge phosphorus ions (31P++) using the gate electrode as a mask. Then a second low impurity concentration source layer and a second low impurity drain layer are formed by tilt angle ion implantation of single charge phosphorus ions (31P+).

Abstract: Methods and apparatus are provided for reducing substrate leakage current of RESURF LDMOSFET devices.

Abstract: A semiconductor substrate that has a MOS transistor with a high breakdown voltage having double sidewall insulation films and can inhibit negative effects on the electric characteristics and method thereof.

Abstract: A transistor can be fabricated to exhibit reduced channel hot carrier effects. According to one aspect of the present invention, a method for fabricating a transistor structure includes implanting a first dopant into a lightly doped drain (LDD) region to form a shallow region therein. The first dopant penetrates the substrate to a depth that is less than the LDD junction depth. A second dopant is implanted into the substrate beyond the LDD junction depth to form a source/drain region. The implantation of the second dopant overpowers a substantial portion of the first dopant to define a floating ring in the LDD region that mitigates channel hot carrier effects.

Abstract: A method (100) of forming a transistor includes forming a gate structure (106, 108) over a semiconductor body and forming recesses (112) substantially aligned to the gate structure in the semiconductor body. Amorphous silicon regions are then formed (114) in the recesses. The amorphous silicon regions are re-crystallized. Sidewall spacers are formed (118) over lateral edges of the gate structure. The method continues by implanting source and drain regions in the semiconductor body (120) after forming the sidewall spacers. The re-crystallized silicon regions formed in the recesses reside close to the transistor channel and serve to facilitate improved carrier mobility in NMOS type transistor devices.

Abstract: A semiconductor device of the present invention includes, as a peripheral MIS transistor 25b, a gate insulating film 13b and a gate electrode 14b provided above an active region 10b, first and second sidewalls 19b and 23b provided on side surfaces of the gate electrode 14b, n-type source and drain regions 24b provided away from each other in the active region, nitrogen diffusion layers 18 provided below the outer sides of the gate electrode 14b, n-type extension regions 16 containing arsenic and provided in regions of the active region 10b located below the outer sides of the gate electrode 14b so that the n-type extension regions 16 cover the inner side surfaces and the bottom surfaces of the nitrogen diffusion layers 18, respectively, and n-type dopant regions 17 containing phosphorus and provided in regions of the active region 10b located below the outer sides of the gate electrode 14b and deeper than the n-type extension regions 16.

Abstract: A method for forming a self-aligned low temperature polysilicon thin film transistor (LTPS TFT). First, active layers of a N type LTPS TFT (NLTPS TFT) and a P type LTPS TFT (PLTPS TFT) are formed on a substrate, and a gate insulating (GI) layer is formed on the substrate. Then, a source electrode, a drain electrode, and lightly doped drains (LDD) of the NLTPS TFT are formed. Further, gate electrodes of the NLTPS TFT and the PLTPS TFT are formed on the gate insulating layer. Finally, the gate electrode of the PLTPS TFT is utilized to form a source electrode and a drain electrode in the active layer of the PLTPS TFT.

Abstract: Provided is a semiconductor device, comprising a gate electrode formed on a semiconductor substrate, source/drain diffusion layers formed on both sides of the gate electrode, a gate electrode side-wall on the side of the source/drain diffusion layer and a gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode and having an L-shaped/reversed L-shaped cross-sectional shape, and a semiconductor layer extending over the gate side-wall insulating film covering a part of the upper surface of the semiconductor substrate in the vicinity of the gate electrode.