Abstract: A method of forming a self-aligned silicide (salicide) with a double gate silicide. The method improves transistor speed by lowering the leakage current in the source and drain areas and lowering the polysilicon sheet resistance of the gate. As a result of one embodiment of the present method, a silicide is formed over the gate area which is advantageously thicker than silicide formations over the source and drain areas.

Abstract: The invention concerns a method for fabricating an electronic component with self-aligned source, drain and gate, comprising the following steps:

Abstract: The present invention discloses methods for fabricating a semiconductor device. A gate electrode having a hard mask layer at its upper portion is formed, and an interlayer insulating film is formed over the resultant structure. A landing plug contact hole is formed by etching the interlayer insulating film, and a conductive layer is formed over the resultant structure, filling up the landing plug contact hole. A first CMP process is performed to expose the hard mask layer, and a second CMP process is preformed to planarize the hard mask layer, the interlayer insulating film and the landing plug conductive layer. The CMP processes of the present invention reduce or prevent dishing of the mask insulating film or contact plug, to reduce or prevent the likelihood of a bridge forming between adjacent conductive plugs. As a result, the semiconductor device has improved properties and/or improved yield.

Abstract: This invention relates to a method for forming a metal oxide semiconductor type field effect transistor (MOSFET), more particularly, to the method for forming the MOSFET by forming a gate and a spacer in a trench. The present invention is used to form the gate and the spacer of the MOSFET in the trench which is preformed in the substrate to reduce the junction depth of the source/drain region. The present invention also can reduce the defects in the drain induced barrier lowering and the punch-through leakage to avoid the spiking leakage defects in the back-end process.

Abstract: The present invention minimizes or eliminates the disadvantages associated with multilevel interconnect structures by providing a method of forming stacked local interconnects that do not extend into higher levels within a multilevel IC device, thereby economizing space available within the IC device and increasing design flexibility. In a first embodiment, the method of the present invention provides a stacked local interconnect which electrically connects a first group of interconnected electrical features with one or more additional isolated groups of interconnected electrical features or one or more isolated individual electrical features. In a second embodiment, the method of the present invention provides a stacked local interconnect which electrically connects an individual electrical feature to one or more additional isolated electrical features.

Abstract: A semiconductor device and method for manufacturing the semiconductor device employing mixed metal silicide technology is disclosed. A semiconductor device is provided having a doped silicon region, such as a source/drain. A first metal layer comprising titanium and a second metal layer comprising nickel are deposited over the semiconductor device. The device is subjected to rapid thermal annealing. The resulting device has a mixed metal silicide layer over the doped silicon region, the mixed metal silicide layer and the doped silicon region having smooth interface between them.

Abstract: The present invention comprises the steps of performing a reforming process on a surface of a low dielectric constant insulation film formed on a substrate which includes one of a porous low dielectric constant insulation film and a non-porous low dielectric constant insulation film and forming an insulation film as at least one of an etching mask and a Chemical Mechanical Polishing stopper (CMP stopper) on the reformed surface of the low dielectric constant insulation film. For example, plasma is radiated as a reforming process mentioned above, the surface roughness of a low dielectric insulation film is increased and, as a result, adhesion between the films and also between the inter-layer insulation film and other neighboring films can be improved with so-called “anchor effect”.

Abstract: A method for forming a wire in a semiconductor device, in forming a titanium film and a titanium nitride film as a barrier metal layer, which can deposit a titanium film and a titanium nitride film each in a different chamber by removing a titanium oxide film used as an insulating film made of upper titanium bonding with oxygen in air as the upper portion of a titanium film is exposed to air by a plasma process and then depositing a titanium nitride film, and as a result can reduce the throughput time of chamber equipment since the partial utilization of the system of the chamber equipment is enabled by driving another chamber even in case one of the chambers breaks down.

Abstract: In a method of fabricating a semiconductor device in which a metal film is formed that is to serve as the diffusion barrier layer material of a plug electrode material that is used when forming a plug electrode on a diffusion layer electrode or a gate electrode in which a metal silicide layer has been formed, increase in the resistance of the plug electrode is prevented. Immediately after the formation of a plug hole by a dry etching method, silicon ions are implanted with an acceleration voltage of at least 20 KeV and at a dosage of at least 1×1013 atoms/cm2, following which a titanium film and a titanium nitride film are formed as the metal film by a sputtering method without carrying out etching by an RF etching method.

Abstract: A nonvolatile semiconductor memory device includes a semiconductor substrate having a main surface, a floating gate electrode having a doped polycrystalline silicon film formed on the main surface with a thermal oxide film therebetween, and a doped polycrystalline silicon film laid over the doped polycrystalline silicon film and having an upward wall, an insulating film covering the doped polycrystalline silicon film, and a control gate electrode formed on the insulating film.

Abstract: To shorten a process for manufacturing a semiconductor device comprising a silicide and a non-silicide diffusion layers and to form a stable and highly homogenous non-silicide diffusion layer, ions are implanted to form a source/drain diffusion layer and then the substrate is subjected to rapid thermal oxidation in a short time to activate the ions while forming a new oxide film. A thermal oxide film (6) consisting of the new oxide film including a protective oxide film (3) is etched to form an oxide film for preventing silicidation (8), a Ti film (9) is formed over the whole surface including the oxide film for preventing silicidation (8), the product is annealed for silicidation and the unreacted Ti film (9) is removed. Thus, a diffusion layer (4) as a non-silicide layer which is little silicided and a diffusion layer (5) whose surface is a silicide layer (10) are formed.

Abstract: Silicide interfaces for integrated circuits, thin film devices, and backend integrated circuit testing devices are formed using a barrier layer, such as titanium nitride, disposed over a porous, thin dielectric layer which is disposed between a silicon-containing substrate and a silicidable material which is deposited to form the silicide interfaces for such devices. The barrier layer prevents the formation of a silicide material within imperfections or voids which form passages through the thin dielectric layer when the device is subjected to a high temperature anneal to form the silicide contact from the reaction of the silicidable material and the silicon-containing substrate.

Abstract: Silicide interfaces for integrated circuits, thin film devices, and backend integrated circuit testing devices are formed using a barrier layer, such as titanium nitride, disposed over a porous, thin dielectric layer which is disposed between a silicon-containing substrate and a silicidable material which is deposited to form the silicide interfaces for such devices. The barrier layer prevents the formation of a silicide material within imperfections or voids which form passages through the thin dielectric layer when the device is subjected to a high temperature anneal to form the silicide contact from the reaction of the silicidable material and the silicon-containing substrate.

Abstract: Coplanar waveguides having a deep trench between a signal line and a ground plane and methods of their fabrication are disclosed. An oxide layer is provided over a silicon substrate and a photoresist is applied and patterned to define areas where the signal line and the ground plane will be formed. A barrier layer is provided over the oxide layer in the defined areas. A metal layer is then deposited over the barrier layer. An etch mask is deposited over the metal layer for the subsequent trench formation. The photoresist and the underlying portion of the oxide and barrier layers are removed and a deep trench is formed in the substrate between the signal line and the ground plane using etching through the mask.

Abstract: A method for manufacturing a semiconductor device including steps of a) preparing an active matrix provided with at least one diffusion region and an insulating layer formed thereon; b) patterning the insulating layer into a predetermined configuration, thereby exposing the diffusion regions; c) forming metal silicide films on the exposed diffusion regions; d) forming a metal layer on the exposed diffusion regions and the insulating layer; e) patterning the metal layer to a preset configuration, thereby obtaining supporting members on the metal silicide films; f) forming bottom electrodes on the supporting members; and g) forming capacitor dielectrics and top electrodes on the bottom electrodes.

Abstract: A layer comprising a second metal silicide as a major constituent element or a layer comprising a second metal as a major constituent element is formed simultaneously by one single chemical vapor deposition process to the bottom surface of two out of there groups of openings etched in a dielectric film on a substrate. A surface comprising silicon as a major constituent element is exposed at each bottom (“through holes or local interconnection holes”) of the first group of openings, a surface comprising a first metal silicide as a major constituent element is exposed at each bottom of the second group of openings, and a surface comprising a first metal as a major constituent element is exposed at each bottom of the third group of openings. The manufacturing method provides low contact resistance and sufficiently small junction leakage current from a diffusion layer in connection with plugs or local interconnections, even if the etched area of the openings are of different depths, shapes, or sizes.

Abstract: A relatively high-resistance first compound film of a semiconductor and a metal is formed on a surface of a semiconductor region in self alignment by a relatively low-temperature first annealing. The relatively high-resistance first compound film is converted into a relatively low-resistance second compound film by a relatively high-temperature second annealing which is done after an insulating film is formed above the first compound film. Hence, the annealing aiming at decreasing a resistance of the compound film can serve as another annealing as well. The number of times of annealing applied to the compound film the resistance of which has been decreased is small, and a thinning effect of the compound film can be suppressed.

Abstract: New compositions and methods for electrolytic deposition of metal layers, including metal traces, (e.g. circuit patterns) that are electrically segregated from adjacent traces in an electronic device, such as a semiconductor wafer or a printed circuit board. The invention includes providing the segregated traces by compositionally modulated plating methods, i.e. for example where a single plating bath (electrolyte) is employed to deposit two different metals at differing current densities or reduction potentials.

Abstract: A process for fabricating composite insulator spacers, comprised of an underlying silicon oxide sidewall layer, and an overlying silicon nitride layer, formed on the sides of a polycide gate structure, has been developed. The process features initially, laterally recessing the exposed sides of a tungsten silicide component, of the polycide gate structure, via use of a selective wet etch solution. A subsequent oxidation procedure, used to thermally grow the silicon oxide sidewall layer, results in a thick silicon oxide component, located on the recessed sides of the tungsten silicide layer, while a thinner silicon oxide component is formed on the sides of the polysilicon component, of the polycide gate structure. Deposition of a silicon nitride layer, followed by an anisotropic RIE procedure, are then used to form the composite insulator spacers, on the sides of the polycide gate structure.

Abstract: The present invention relates to a method of reducing Si consumption during a self-aligned silicide process which employs a M—Si or M—Si—Ge alloy, where M is Co, Ni or CoNi and a blanket layer of Si. The present invention is particularly useful in minimizing Si consumption in shallow junction and thin silicon-on-insulator (SOI) electronic devices.

Abstract: A method for forming an interconnection of a semiconductor device including a step of sequentially stacking a first insulation layer, a first semiconductor layer, a barrier metal layer and a second semiconductor layer on a semiconductor substrate, a step of forming an amorphous first tungsten silicide layer on the second semiconductor layer, a step of transforming the first tungsten silicide layer into a second tungsten silicide layer having a tetragonal crystal structure by an annealing process; a step of forming an etching mask on the second tungsten silicide layer, and a step of sequentially selectively etching the second tungsten silicide layer, the second semiconductor layer, the barrier metal layer and the first semiconductor layer by employing the etching mask.

Abstract: A transistor device formed on a semiconductor-on-insulator (SOI) substrate with a buried oxide (BOX) layer disposed thereon and an active layer disposed on the BOX layer having active regions defined by isolation trenches. The device includes a gate defining a channel interposed between a source and a drain formed within the active region of the SOI substrate. Further, the device includes a multi-thickness silicide layer formed on the main source and drain regions and source and drain extension regions wherein a portion of the multi-thickness silicide layer which is formed on the source and drain extension regions is thinner than a portion of the silicide layer which is formed on the main source and drain regions. The device further includes a second thin silicide layer formed on a polysilicon electrode of the gate.

Abstract: A method for manufacturing a transistor includes providing a transistor assembly having a semiconductor layer with a first surface, a dielectric layer disposed on the first surface, a gate electrode disposed on the dielectric layer, an insulation layer adjacent at least part of the gate electrode, and a nitride spacer layer adjacent at least part of the insulation layer. The method also includes depositing, on part of the first surface, a material that will react with the semiconductor layer to form silicide and removing the unreacted material. The method further includes etching the nitride spacer layer, depositing a pre-metal spacer layer adjacent at least part of the nitride spacer layer and at least part of the first surface, etch removing a portion of the pre-metal spacer layer to expose part of the silicided portion of the first surface, and forming a contact with the silicided portion of the first surface.

Abstract: A method of making a vertical diode is provided, the vertical dioxide having associated therewith a diode opening extending through an insulation layer and contacting an active region on a silicon wafer. A titanium silicide layer covers the interior surface of the diode opening and contacts the active region. The diode opening is initially filled with an amorphous silicon plug that is doped during deposition and subsequently recrystallized to form large grain polysilicon. The silicon plug has a top portion that is heavily doped with a first type dopant and a bottom portion that is lightly doped with a second type dopant. The top portion is bounded by the bottom portion so as not to contact the titanium silicide layer. For one embodiment of the vertical diode, a programable resistor contacts the top portion of the silicon plug and a metal line contacts the programmable resistor.

Abstract: A low k interlevel dielectric layer fabrication method includes providing a substrate having integrated circuitry at least partially formed thereon. An oxide comprising interlevel dielectric layer comprising carbon and having a dielectric constant no greater than 3.5 is formed over the substrate. After forming the carbon comprising dielectric layer, it is exposed to a plasma comprising oxygen effective to reduce the dielectric constant to below what it was prior to said exposing. A low k interlevel dielectric layer fabrication method includes providing a substrate having integrated circuitry at least partially formed thereon. In a chamber, an interlevel dielectric layer comprising carbon and having a dielectric constant no greater than 3.5 is plasma enhanced chemical vapor deposited over the substrate at subatmospheric pressure.

Abstract: A semiconductor device having a self-aligned contact hole is formed by providing a side wall oxide film on a gate electrode, covering the gate electrode and the side wall oxide film by an oxide film and further covering the oxide film by a nitride film, wherein the oxide film is formed by a plasma CVD process with a reduced plasma power such that the H2O content in the oxide film is less than about 2.4 wt %.

Abstract: A wiring of silicon is formed on a surface of a semiconductor substrate. Part of the wiring is covered with a resist pattern. Ion implantation is conducted on the substrate using the resist pattern as a mask and then the resist pattern is removed. An upper section of the wiring with a thickness of at least 5 nm is removed to minimize thickness of the wiring. Reaction is caused between a surface section of the wiring of which thickness is thus reduced and a metal which reacts with silicon to form suicide to thereby form a metal silicide film on a surface of the wiring. Resistance of the wiring can be reduced with good reproducibility.

Abstract: The invention encompasses a method of forming a silicon-doped aluminum oxide. Aluminum oxide and silicon monoxide are co-evaporated. Subsequently, at least some of the evaporated aluminum oxide and silicon monoxide is deposited on a substrate to form the silicon-doped aluminum oxide on the substrate. The invention also encompasses methods of forming transistors and flash memory devices.

Abstract: A semiconductor device having a bump electrode comprising a copper contact pad on a substrate wherein at least a portion of the copper contact pad is exposed through the dielectric layer on the substrate. The copper contact pad is provided with an under bump metallurgy including a titanium layer formed on the portion of the copper contact pad, a nickel-vanadium layer formed on the titanium layer and a copper layer formed on the nickel-vanadium layer. A metal bump provided on the UBM over each copper contact pad so as to form bump electrode. The UBM of the present invention is characterized by using the nickel-vanadium layer as barrier layer thereby significantly reducing the required thickness of the titanium layer, and thereby reducing cost and enhancing reliability.

Abstract: Silicide interfaces for integrated circuits, thin film devices, and backend integrated circuit testing devices are formed using a barrier layer, such as titanium nitride, disposed over a porous, thin dielectric layer which is disposed between a silicon-containing substrate and a silicidable material which is deposited to form the silicide interfaces for such devices. The barrier layer prevents the formation of a silicide material within imperfections or voids which form passages through the thin dielectric layer when the device is subjected to a high temperature anneal to form the silicide contact from the reaction of the silicidable material and the silicon-containing substrate.

Abstract: The present invention provides a method of manufacturing a nickel-silicide technology for polysilicon interconnects. Nickel 40 is deposited on polysilicon 30 using a electroless process. Using a rapid thermal anneal process, Ni 40 is transformed to NiSi at about 600° C. without any agglomeration. The method comprises forming a polysilicon layer 30 over a substrate 10. The surface 34 of the polysilicon layer is activated. Nickel 40 is selectively electroless deposited onto the surface of the polysilicon layer forming a Nickel layer over the polysilicon layer. The Ni layer 40 is rapidly thermally annealed forming a Nickel silicide layer 36 over the polysilicon layer 30. The rapid thermal anneal is performed at a temperature of about 600° C. for a time of about 40 sec. The Nickel silicide layer 36 preferably comprises NiSi 36B with a low resistivity.

Abstract: At least one patterned dielectric layer is provided within a transistor arrangement to prevent a local interconnect from electrically contacting,the gate conductor due to misalignments during the damascene formation of etched openings used in forming local interconnects. By selectively etching through a plurality of dielectric layers during the local interconnect etching process, the patterned dielectric layer is left in place to prevent short-circuiting of the gate to an adjacent local interconnect that is slightly misaligned.

Abstract: A method of reducing the gate resistance in a semiconductor device forms a gate in the semiconductor device followed by the creation of a silicide region on top of the gate. During the initial formation of the silicide region on the gate, formation of silicide on source/drain areas of the semiconductor device is prevented by a shielding material. The shielding material is then removed and additional silicide is created, forming silicide regions on the source/drains and increasing the thickness of the silicide over the gate, thereby lowering the gate resistance.

Abstract: A method for forming a thermally stable cobalt disilicide film in the fabrication of an integrated circuit is described. A semiconductor substrate is provided having silicon regions to be silicided. A cobalt layer is deposited overlying the silicon regions to be silicided. A capping layer is deposited overlying the cobalt layer. The substrate is subjected to a first rapid thermal anneal whereby the cobalt is transformed to cobalt monosilicide where it overlies the silicon regions and wherein the cobalt not overlying the silicon regions is unreacted. The unreacted cobalt layer and the capping layer are removed. A titanium layer is deposited overlying the cobalt monosilicide layer. Thereafter the substrate is subjected to a second rapid thermal anneal whereby the cobalt monosilicide is transformed to cobalt disilicide. The titanium layer provides titanium atoms which diffuse into the cobalt disilicide thereby increasing its thermal stability.

Abstract: The objective of the invention is to make the n-type silicon region, that relatively strongly and adversely affects the dependence of titanium silicide resistance on wire thickness, as small as possible, in common gate electrode wiring with a CMOS structure. The region, into which ions of n-type impurity 6 are implanted, is only the element region of a p-type substrate region, and all the rest of the gate electrode wiring, on the n-type substrate region and field region, is constituted by p-type polysilicon, with relatively good low-resistance titanium silicide formation.

Abstract: To provide a high-performance semiconductor integrated circuit in which the standby current is reduced by preventing current leakage in a semiconductor integrated circuit device, for example, the memory cell of an SRAM.

Abstract: A method for making a flexible metal silicide local interconnect structure. The method includes forming an amorphous or polycrystalline silicon layer on a substrate including at least one gate structure, forming a layer of silicon nitride over the silicon layer, removing a portion of the silicon nitride layer, oxidizing the exposed portion of the silicon layer, removing the remaining portion of the silicon nitride layer, optionally removing the oxidized silicon layer, forming a metal layer over the resulting structure, annealing the metal layer in an atmosphere comprising nitrogen, and removing any metal nitride regions. The local metal silicide interconnect structure may overlie the at least one gate structure. The methods better protect underlying silicon regions (e.g., substrate), as well as form TiSix local interconnects with good step coverage. Intermediate and resulting structures are also disclosed.

Abstract: A method of forming a contact structure in a semiconductor device is provided. In this method, a semiconductor layer, an ohmic metal layer, and a barrier metal layer are formed on the surface of a semiconductor substrate on which a metal contact hole has been formed. A compound material layer having a uniform thickness is formed on the bottom, sidewalls and lower corners of the contact hole by thermally reacting the semiconductor layer with the ohmic metal layer. Accordingly, when the contact hole exposes an impurity layer and portions of an isolation layer adjacent to the impurity layer, the junction leakage current characteristics of the impurity layer and a contact resistance are improved.

Abstract: A method is provided, the method comprising forming a first dielectric layer above a first structure layer, forming a first opening in the first dielectric layer, and forming a first copper structure above the first dielectric layer and in the first opening. The method also comprises annealing the first copper structure using one of a furnace anneal process performed at a temperature ranging from approximately 100-400° C. for a time ranging from approximately 10-90 minutes and a rapid thermal anneal (RTA) process performed at a temperature ranging from approximately 100-400° C. for a time ranging from approximately 10-180 seconds.

Abstract: Shorting between a transistor gate electrode and associated source/drain regions due to metal silicide formation on the sidewall spacers is prevented by passivating the sidewall spacer surfaces with a solution of iodine and ethanol. Embodiments of the invention include spraying the wafer with or immersing the wafer in, a solution of iodine in ethanol.

Abstract: A method of manufacturing a MOSFET semiconductor device comprises providing a gate electrode having first and second opposing sidewalls over a substrate having source/drain regions; providing a gate oxide between the gate electrode and the substrate; forming first and second sidewall spacers respectively disposed adjacent the first and second sidewalls; forming nickel silicide layers disposed on the source/drain regions and the gate electrode, and two etching steps. The nickel silicide layers are formed during a rapid thermal anneal at temperatures from about 380 to 600° C. The first etch is performed with a sulfuric peroxide mix to remove unreacted nickel, and the second etch is performed with an ammonia peroxide mix to remove nickel silicide formed over the first and second sidewall spacers.

Abstract: Metal nitride and metal oxynitride extrusions often form on metal silicides. These extrusions can cause short circuits and degrade processing yields. The present invention discloses a method of selectively removing such extrusions. In one embodiment, a novel wet etch comprising an oxidizing agent and a chelating agent selectively removes the extrusions from a wordline in a memory array. In another embodiment, the wet etch includes a base that adjusts the pH of the etch to selectively remove certain extrusions relative to other substances in the wordline. Accordingly new metal silicide structures can be used to form novel wordlines and other types of integrated circuits.

Abstract: The present invention provides a method for wiring, which plugs conductive material sufficiently into a via hole produced in dielectronics (hereinafter, referred to as “a via hole”) and prevents generating a void. The via hole is made through a via hole patterning step and a cleaning step. At a surface treatment step, substance having chemical affinity (active site) is adsorbed to the surface of the via hole. Next, an electron donative layer is made by depositing substance having an electron donative characteristic on the active sites acting as cores at an electron donative layer formation step. Then, the wiring material is plugged at a via hole plug step.

Abstract: A SEG combined with tilt implant method for forming semiconductor device is disclosed. The method includes providing a semiconductor structure which comprises an active area in between isolation regions in a substrate with the active area having a gate electrode formed thereon, wherein a spacer is formed on the sidewall of said gate electrode. Then, selective epitaxial growth regions are formed on the active area and the gate electrode. Next, the active area is implanted with an angle to form source/drain regions beside the bottom edge of the gate electrode. Then, the salicide process and backend processes are performed.

Abstract: A method of forming a self-aligned silicide layer. A planarization process is performed to form a gate with a planar top surface. Due to the planar top surface of the gate, the reactivity and the uniformity of thickness of the subsequently formed silicide layer on the top surface of the gate are improved, such that the resistance of the silicide is reduced, and the performance of the device is improved.

Abstract: A TiN film is selectively formed as a barrier layer on a Cu metal layer by selective removal of a Ti metal layer on the Si metal layer after the following steps of selectively forming a Si metal layer as an etching mask on an insulation film, forming a trench pattern by selective removal of the insulation film using the Si metal layer, forming a Cu metal layer in the trench pattern with the Si metal layer remained, forming the Ti metal layer on the Si metal layer and the Cu metal layer as a barrier material with a different kind of eutectic reaction with Cu from the reaction with the etching mask by heat-treatment in an atmosphere of nitrogen, and selectively nitriding the Ti metal layer on the Cu metal layer by heat-treatment of the Ti metal layer in an atmosphere of nitrogen.

Abstract: A method of fabricating a copper capping layer. A silicon rich nitride layer is formed on an exposed copper layer. Since the silicon rich nitride layer has more dangling bonds inside, the silicon in the silicon rich nitride layer easily reacts with the copper and a copper silicide layer is formed between the copper and the silicon rich nitride layer. Therefore, adhesion of the copper and the silicon rich nitride layer can be improved.

Abstract: In producing a thin film transistor used for such devices as a large-sized liquid crystal display panel with a high pixel density, a leftover of an insulating film caused by insufficient etching and a loss of a semiconductor layer caused by overetching are prevented, and a reliable electrical contact between the source and drain electrodes and the semiconductor layer is achieved. These are achieved by (a) forming a contact hole region of a silicon film so that the region has a larger thickness, for example, by making the film to have a plurality of layers, and (b) providing a silicide layer between an electrode metal and the semiconductor layer.

Abstract: A method of fabricating a self-align-contact is provided. A first gate and a second gate are formed on a semiconductor substrate. A spacer is formed on the sidewalls of the first gate and the second gate, and a source/drain region is formed between the first gate and the second gate. A dielectric layer is formed on the first gate, the second gate, the source/drain region, the spacer, and the semiconductor substrate. A self-align-contact opening is formed in the dielectric layer to expose the source/drain region. A metal silicide layer is formed on the source/drain region. A first conductive layer, such as doped polysilicon, is formed on the metal silicide layer and in the self-align-contact opening. A second conductive layer is formed on the first conductive layer, and the first conductive layer and the second conductive layer are patterned.

Abstract: A process for manufacturing a semiconductor device having a lower wiring layer, an interlayer insulating film and an upper wiring layer in this order and a connection hole formed in the interlayer insulating film on the lower wiring layer, wherein the connection hole is provided by the steps of: forming a photoresist layer on the interlayer insulating film; and forming in the photoresist layer an opening for the connection hole which exposes the interlayer insulating film at the bottom thereof and an opening for a dummy connection hole which does not expose the interlayer insulating film at the bottom thereof.