Abstract: The present invention is intended for use on BiCMOS technology where the BJTs are formed after the FETs. A thin FET protection layer 26 is deposited on the raised and recessed regions 28 of the semiconductor substrate 10. A selectively removable filler layer 30 is then deposited on the FET protection layer 26 with a thickness to over-fill the recessed regions 28 of the gates 24 of the FETs. The selectively removable filler layer 30 is then planarized until the FET protection layer 26 on top of the gates 24 is exposed. The recessed regions 28 between the gates 24 are left substantially filled with selectively removable filler layer 30. The selectively removable filler layer 30 in the region where the BJT is formed is patterned and an opening 32 is made to allow for the depositing of layers of different materials 34, 36, 38, 40, 42, 44 used in the construction of the BJT. The layer of different materials 34, 36, 38, 40, 42, 44 are processed by methods known in the art to form polysilicon emitter 46 of the BJT.

Abstract: The invention provides a technology for reducing the direct contact resistance and for reducing the junction leak while maintaining the punch through margin. A semiconductor integrated circuit device is provided which comprises: a substrate; a transistor formed on the substrate, which comprises a source, a drain and a gate which controls a current flowing from said source to said drain; and a contact plug being electrically connected to at least one of the source and drain and made of a conductive material including a dopant. The contact plug is formed of at least a first layer and a second layer. The first layer contacts with one of the source and drain and is made of said material including the dopant of a first concentration. The second layer is formed of a layer of said material including the dopant of a second concentration, which is lower than the second concentration.

Abstract: A contact forming method of a semiconductor device is disclosed, in which a pad polysilicon layer is formed at an active region of a cell array, thereafter an upper portion of a gate is opened when a spacer of a NMOS transistor region is formed. And at the same time a gate capping insulating layer of the cell array region, the active region of the NMOS transistor and the gate node contact region remains at a predetermined thickness by etching the spacer. And then, by performing an ion implantation procedure on the entire surface, the direct pad polysilicon layer and the buried pad polysilicon layer are simultaneously ion-implanted.

Abstract: A method and system to form a refractory metal layer on a substrate features a bifurcated deposition process that includes nucleating a substrate using ALD techniques to serially expose the substrate to first and second reactive gases followed forming a bulk layer, adjacent to the nucleating layer, using CVD techniques to concurrently exposing the nucleation layer to the first and second gases.

Abstract: In accordance with one embodiment of the present invention, a method of interfacing a poly-metal stack and a semiconductor substrate is provided where an etch stop layer is provided in a polysilicon region of the stack. The present invention also addresses the relative location of the etch stop layer in the polysilicon region and a variety of stack materials and oxidation methods. The etch stop layer may be patterned within the poly or may be a continuous conductive etch stop layer in the poly. The present invention also relates more broadly to a process for forming wordline architecture of a memory cell. In accordance with another embodiment of the present invention, a semiconductor structure is provided comprising a poly-metal stack formed over a semiconductor substrate where the interface between an oxidation barrier placed over the stack and an oxidized portion of the stack lies along the sidewall of the poly.

Abstract: A polysilicon layer is formed on a semiconductor substrate followed by performing a collimator physical vapor deposition (PVD) process to form a titanium nitride layer on the polysilicon layer. A rapid thermal nitridation (RTN) process is then performed to tighten the structure of the titanium nitride layer. Finally, a silicide layer is formed on the barrier layer. By using the titanium nitride layer, the interface between the silicide layer and the polysilicon layer is effective prevented from occurring a spike.

Abstract: A method for forming silicide, at least includes following essential steps: provide substrate which is covered with semiconductor structure which has rugged surface; form silicon layer on semiconductor structure; form a metal layer on silicon layer; form capping layer on metal layer; and perform thermal process to form silicide layer by reacting of metal layer and silicon layer, where the thermal stability of capping layer is superior to the thermal stability of silicide layer. The method further perform a pattern process to form numerous conductive lines at least are made of silicide layer. One main characteristic of this invention is to limit agglomeration of silicide by high thermal stable capping layer, such that occurrence of electrical open induced by open of silicide is reduced.

Abstract: The invention includes a method of fabricating a circuit in a manner to place certain structures within a predefined distance of one another. Electrical connections are formed between certain structures of silicon, by annealing a conductive material to cause silicon out-diffusing to form local interconnects. The silicon out-diffusion can be facilitated without a masking step thereby simplifying as well as speeding up the fabrication process. The invention also includes a local interconnect thus formed.

Abstract: A method of fabricating a semiconductor device having the steps of forming an insulating layer on a silicon substrate; forming a contact hole in the insulating layer so that a portion of the silicon substrate is exposed in the contact hole; performing an interface treatment process to the exposed portion of the silicon substrate, wherein the interface treatment process includes at least a dry cleaning and a hydrogen heat treatment; and forming a selective silicon plug including single crystalline and polycrystalline silicon structures on the exposed portion of the silicon substrate.

Abstract: Method for fabricating a polycide dual gate in a semiconductor device fabricates a dual gate having polycide gate electrodes. The polycide can be a cobalt polycide, for example. The method can include forming polysilicon pattern layers on a first and a second regions of a semiconductor substrate, forming a blocking layer to expose top surfaces of the polysilicon pattern layers and mask the substrate, and forming a metal layer on an entire surface and then is annealed to form a gate electrode having a stack of the polysilicon pattern layer under a silicide layer. Impurity ions of opposite conductivities in the first and second regions can be respectively deposited and diffused to form source/drain regions in surfaces of the substrate on both sides of the gate electrode. The implanted impurity ions can further implant ions in the silicide/polysilicon pattern layer gate to reduce fabrication steps or simplify the fabrication process.

Abstract: The invention encompasses methods of forming silicide interconnects over silicon comprising substrates. In one implementation, a first layer comprising a metal and a non-metal impurity is formed over a region of a silicon comprising substrate where a silicide interconnection is desired. An elemental metal comprising second layer is formed over the first layer. The substrate is annealed to cause a reaction between at least the elemental metal of the second layer and silicon of the substrate region to form a silicide of the elemental metal of the second layer. In another considered aspect, a method of forming a silicide interconnect over a silicon comprising substrate includes providing a buffering layer to silicon diffusion between a refractory metal comprising layer and a silicon containing region of a substrate.

Abstract: Within a method for fabricating a microelectronic fabrication having formed therein a copper containing conductor layer passivated with a passivation layer, there is first: (1) pre-heated the copper containing conductor layer to a temperature of from about 300 to about 450 degrees centigrade for a time period of from about 30 to about 120 seconds to form a pre-heated copper containing conductor layer; and then (2) plasma treated the pre-heated copper containing conductor layer within a reducing plasma to form a plasma treated pre-heated copper containing conductor layer; prior to (3)forming upon the plasma treated pre-heated copper containing conductor layer the passivation layer. The foregoing process sequence provides for attenuated hillock defects within the plasma treated pre-heated copper containing conductor layer when forming the passivation layer thereupon.

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 present invention provides a semiconductor device in which a low resistance, tunable contact is formed by means of using a SixGe1−x (0<x<1) layer. Thus, only moderate doping is required, which in turn protects the device from short channel effect and leakage. The low resistance, tunable contact is suitable for CMOS devices.

Abstract: Polishing pad glazing during CMP of Al and Al alloys is eliminated or substantially reduced by utilizing a neutral polishing slurry containing a sufficient amount of a surfactant to prevent agglomeration of the abrasive particles with polishing by-products. Embodiments include CMP an Al or an Al alloy surface employing a slurry containing abrasive Al203 particles and about 0.02 to about 5 wt. % of a surfactant to prevent Al203 abrasive slurry particles from agglomerating with Al(OH)3 polishing by-products. Embodiments further include subsequent ex situ pad conditioning using an acid or base to dissolve, or a complexing agent to remove, Al(OH)3 polishing by-products.

Abstract: A method of forming a film on a substrate using one or more complexes containing one or more chelating O- and/or N-donor ligands. The complexes and methods are particularly suitable for the preparation of semiconductor structures using chemical vapor deposition techniques and systems.

Abstract: A method of forming spaces between polysilicon lines can include patterning structures having top SiON layers and bottom amorphous carbon layers where the structures are located over a polysilicon layer and are separated by a first width, forming amorphous carbon spacers along lateral side walls of the patterned structures, etching apertures into the polysilicon layer not covered by the amorphous carbon spacers and the patterned structures where the apertures in the polysilicon layer between adjacent patterned structures have a second width, and ashing away the amorphous carbon spacers and the patterned structures. The second width is less than the first width.

Abstract: A method and structure for a device with a signal line over a semiconductor structure where the signal line is formed over the ground plane, passivation layer, and polyimide layer. We provide a semiconductor structure comprising a substrate having devices formed thereover and a plurality of insulating and conductive layers thereover. Next, we form ground plane over the semiconductor structure. The ground plane is the top metal layer over an inter metal dielectric layer. We then form a passivation layer over the ground plane. We form a first dielectric (e.g., polyimide) layer over the passivation layer. Subsequently, we form a signal line over the first dielectric layer. The signal line is formed by a plating or printing. We form a second dielectric layer (e.g., polyimide) over the signal line and the first dielectric layer.

Abstract: A method of forming a metal seed layer, preferably a copper layer, for subsequent electrochemical deposition. The metal seed layer is formed by the oxidation-reduction reaction of a metal salt with a reducing agent present in a layer on the substrate to be plated. Metal interconnects for semiconductor devices may be produced by the method, which has the advantage of forming the metal seed layer by a simple electrochemical plating process that may be combined with the plating of the interconnect itself as a single-bath operation.

Abstract: Self-aligned floating gates are formed to have precisely defined lengths and positions. The floating gates are formed by first forming a number of shallow trench isolation regions that have substantially planar top surfaces that lie above the top surface of the semiconductor material. A layer of dielectric is formed on the semiconductor material, followed by the formation of a first layer of polysilicon. The first layer of polysilicon is then planarized so that the first layer of polysilicon is removed from the isolation regions. In subsequent steps, the polysilicon is again etched to form the floating gates. As a result of the planarization, the lengths of the floating gates are defined by the spacing between isolation regions, and the positions of the floating gates are precisely defined.

Abstract: Doped polysilicon layers and layered polysilicon structures are produced, and the layers and layered structures are structured. The doping is distinguished by the fact that the doping compound is added as a process gas during the chemical vapor deposition of the polysilicon to define the doping profile. The feed of dopant to the process gas is stopped toward the end of the vapor deposition, with the result that a boundary layer of undoped silicon is deposited. As a result, a favorable surface quality and better adhesion to a neighboring layer is obtained. The structuring process comprises an at least three-step etching process in which a fluorine containing gas is used for etching in a first step, a chlorine-containing gas is used for etching in a second step and a bromine-containing, gas is used for etching in a third step. The invention also encompasses wafers and semiconductor chips produced with the novel doping and/or structuring method.

Abstract: Polysilicon gates are formed with greater accuracy and consistency by depositing a silicon carbide antireflective layer on the polysilicon layer before patterning. Embodiments also include depositing the polysilicon layer and the silicon carbide layer in the same tool.

Abstract: A method of fabricating the semiconductor device for preventing polysilicon line from being damaged during removal of a photoresist layer. The method begins by forming polysilicon lines on a core device region and an electrostatic discharge protection device region of a substrate. A plurality of offset spacers is formed on sidewalls of the polysilicon lines. After the offset spacers are formed, a photoresist layer is formed over the substrate to cover the core device region, while exposing the electrostatic discharge protection device region. With the photoresist layer serving as a mask, a punch-through ion implantation is performed on the electrostatic discharge protection device region before the photoresist layer is removed. Next, a plurality of lightly doped source/drain regions is formed in the core device region. A spacer is further formed on the edge of the offset spacer, followed by forming source/drain regions in the core device region and the electrostatic discharge protection device.

Abstract: An integrated raised contact formation method to achieve ultra shallow junction devices is described. Semiconductor device structures are provided in and on a substrate and covered with a dielectric layer. The dielectric layer is etched through to form first openings to the substrate. The surface of the substrate exposed within the first openings is amorphized. A silicon layer is selectively formed on the amorphized substrate surface. Then, ions are implanted into the silicon layer to form raised contacts. Thereafter, the dielectric layer is etched through to form second openings to gates. The first and second openings are filled with a conducting layer to complete formation of contacts in the fabrication of an integrated circuit device.

Abstract: A semiconductor device which can reduce contact resistance, is disclosed. A semiconductor device according to the present invention includes a lower conductor pattern and an upper conductor pattern. The lower conductor pattern is in contact with the upper conductor pattern. The lower conductor pattern includes a first doped polysilicon layer, a first tungsten silicide layer and a cap layer formed sequentially. Here, the cap layer is formed to a doped polysilicon layer containing a small amount of tungsten and has stoichiometrical equivalent ratio x of Si higher than the first tungsten silicide layer. The upper conductor pattern includes a second doped polysilicon layer and a second tungsten layer formed sequentially. The contact of lower conductor pattern and the upper conductor pattern is substantially formed between the cap layer and the second doped polysilicon layer. Preferably, stoichiometrical equivalent ratio x of Si for the first tungsten silicide layer is 2.3 to 2.

Abstract: Disclosed herein is a method of manufacturing a semiconductor capacitor. In the semiconductor capacitor manufacturing method, an amorphous film composed of non-doped silicon is formed. The amorphous film is changed to a lower film having projections and depressions defined in the surface thereof by heat treatment. An amorphous film composed of impurity-doped silicon is formed over the surface of the lower film. Further, the amorphous film composed of the impurity-doped silicon is changed to an upper film having projections and depressions defined in the surface thereof by heat treatment with the projections and depressions provided over the surface of the lower film as a basis. The semiconductor capacitor is equipped with an electrode having the lower film and the upper film.

Abstract: The crystallization method by laser light irradiation forms a multiplicity of convexes (ridges) in the surface of an obtained crystalline semiconductor film, deteriorating film quality. Therefore, it is a problem to provide a method for forming a ridge-reduced semiconductor film and a semiconductor device using such a semiconductor film. The present invention is characterized by heating a semiconductor film due to a heat processing method (RTA method: Rapid Thermal Anneal method) to irradiate light emitted from a lamp light source after crystallizing the semiconductor film by laser light, thereby reducing the ridge.

Abstract: A method and structure providing N-profile engineering at the poly/gate oxide and gate oxide/Si interfaces of a layered polysilicon/amorphous silicon structure of a semiconductor device. NH3 annealing provides for the introduction of nitrogen to the interface, where the nitrogen suppresses Boron diffusion, improves gate oxide integrity, and reduces the sites available for trapping hot carriers which degrade device performance.

Abstract: According to various embodiments of the present invention, a bonding pad structure of a semiconductor device reduces damage caused by thermo-mechanical stress in beam lead bonding. A method of fabricating an improved bonding pad structure is also provided. A polysilicon film plate is preferably formed between a bonding pad metal layer and a dielectric layer. The polysilicon film plate absorbs external thermo-mechanical stress and improves the durability of the bonding pad in a bond pull test (BPT). The bonding between the bonding pad metal layer and the dielectric layer is also improved. Other features and advantages are also provided.

Abstract: A method for producing a micromechanical structure, and a micromechanical structure having a movable structure and a stationary structure made of silicon. In the method for producing the micromechanical structure, in one process step, a superficial metal-silicide layer is produced in the movable structure and/or the stationary structure.

Abstract: A semiconductor device and a process for forming the device includes a conductor that overlies an insulating layer. In one embodiment, the conductor includes a first conductive portion, a second conductive portion, and a third conductive portion. The second conductive portion lies between the first and third conductive portions. The first conductive portion includes a first element, and the third conductive portion includes a metal and silicon without a significant amount of the first element. In another embodiment, the conductor is a gate electrode or a capacitor electrode. The conductor includes a first conductive portion, a second conductive portion, a third conductive portion, and a fourth conductive portion. The second conductive portion lies between the first and third conductive portions and has a different composition compared to the first, third, and fourth conductive portion.

Abstract: The present invention provides a method for controlling dopant density of a plug-shaped doped polysilicon layer formed within a plug-shaped recess to prevent the dopant contained in the plug-shaped doped polysilicon layer from diffusing into a conductive layer under the plug-shaped recess through a bottom side of the plug-shaped recess, the plug-shaped recess being formed within a dielectric layer which is positioned above the conductive layer, the method comprising: (1) forming an undoped silicon layer on the surface of the plug-shaped recess; (2) forming a doped polysilicon layer on top of the undoped silicon layer to fill the plug-shaped recess; and (3) performing a thermal treatment to the semiconductor wafer so as to make the doped poly-silicon layer interact with the undoped silicon layer inside the plug-shaped recess which forms a completely doped polysilicon layer within the plug-shaped recess.

Abstract: Field effect transistor 22 comprises a gate insulator layer 12 formed on an outer surface of substrate 10. Composite gate stack 24 comprises the gate insulator layer 12, a silicide layer 18 and a polycrystalline semiconductor layer 20. Silicide layer 18 is formed by reacting an inner polycrystalline semiconductor layer 16 and a metal layer 14. Silicide layer 18 reduces carrier depletion effect because of its higher carrier density.

Abstract: A process for fabricating system-on-chip devices which contain embedded DRAM along with other components such as SRAM or logic circuits is disclosed. Local interconnects, via salicides and tungsten are formed subsequent to polysilicon plugs required for the operation of the DRAM and SRAM or logic. Also disclosed are systems-on-chips MIM/MIS capacitive devices produced by the inventive process.

Abstract: In the fabrication of EDRAM/SDRAM silicon chips with ground rules beyond 0.18 microns, a Si3N4 barrier layer is deposited onto the patterned structure during the borderless polysilicon contact fabrication. It is required that this layer be conformal and has a high hydrogen atom content to prevent junction leakage. These objectives are met with the method of the present invention. In a first embodiment, the Si3N4 layer is deposited in a Rapid Thermal Chemical Vapor Deposition (RTCVD) reactor using a NH3/SiH4 chemistry at a temperature and a pressure in the 600-950° C. and 50-200 Torr ranges respectively. In a second embodiment, it is deposited in a Low Pressure Chemical Vapor Deposition (LPCVD) furnace using a NH3/SiH2Cl2 chemistry (preferred ratio 1:1) at a temperature and a pressure in the 640-700° C. and 0.2-0.8 Torr ranges respectively.

Abstract: Methods are disclosed for the fabrication of novel polysilicon structures having increased surface areas to achieve lower resistances after silicidation. The structures are applicable, for example, to semiconductor interconnects, polysilicon gate, and capacitor applications. The inventive method provides additional means of obtaining suitable sheet resistivity and resistances for deep submicron applications. Techniques are disclosed for improving the conductivities of a silicided gate structure, a silicided interconnect structure, and capacitor component structures, each of such are situated on a substrate assembly, such as a semiconductor wafer.

Abstract: A method and apparatus for selectively depositing hemispherical grained silicon on the surface of a wafer in a process chamber. The chamber is evacuated so that a partial pressure of water vapor in the chamber is less than 10−7 torr, preferably using a turbomolecular pump and a water vapor pump in cooperation. A process gas mixture including silicon is introduced into the chamber. The surface of the wafer is seeded with silicon nuclei, and the wafer is annealed to convert the silicon to HSG.

Abstract: A method for forming an electrical interconnect overlying a buried contact region of a substrate is characterized by a deposition of a first polycrystalline silicon layer and the patterning and etching of same to form a via. The via is formed in the first polycrystalline silicon layer to expose the substrate and a second polycrystalline silicon layer is formed in the via to contact the substrate. Portions of the second polycrystalline silicon layer overlying the first polycrystalline silicon layer are removed eliminating any horizontal interface between the two polycrystalline silicon layers. The first polycrystalline silicon layer remaining after the etch is then patterned to form an electrical interconnect.

Abstract: The present invention provides a semiconductor memory device and a fabrication method capable of preventing the contact between a dielectric layer of a capacitor and a diffusion barrier. The plug comprises a diffusion barrier layer and a seed layer for forming a lower electrode of a capacitor. Accordingly, it is possible to prevent the dielectric layer being contacted with the diffusion barrier, whereby the leakage current may be reduced, and the capacitance of the capacitor may be increased.

Abstract: A process for fabricating a capacitor in a microcircuit, and the capacitor so fabricated. A first layer of a polycrystalline semiconductor, preferably polysilicon, is deposited. A layer of a binary metallic conductor, preferably tungsten silicide, is deposited on the first layer of polycrystalline semiconductor, and is annealed in an oxidizing atmosphere to produce an oxide layer that serves as the dielectric of the capacitor. A second layer of a polycrystalline semiconductor, also preferably polysilicon, is deposited on the oxide layer. The physical properties (index of refraction, charge to breakdown, breakdown voltage) of the dielectric so created are superior to those of the prior art dielectrics.

Abstract: Disclosed is a method for forming gate electrodes using tungsten formed on a tungsten nitride layer by the chemical vapor deposition(CVD) process rather than the physical vapor deposition(PVD) process. According to the method for forming gate electrodes of the present invention, a silicon layer is formed as a conductive layer for gate electrodes. A tungsten nitride layer is formed on the silicon layer, and then the tungsten nitride layer is thermally treated thereby making a surface of the tungsten nitride layer a first tungsten layer. Next, a second tungsten layer is formed by using the first tungsten layer as a nucleation layer according to the CVD process. According to the present method for forming gate electrodes, tungsten can be deposited by the CVD process rather than by the PVD process. Therefore, those problems such as washing equipment and the particle source which are necessarily accompanied with the PVD process can be prevented, thereby improving productivity and yield.

Abstract: This invention is a process for forming an effective titanium nitride barrier layer between the upper surface of a polysilicon plug formed in a thick dielectric layer and a platinum lower capacitor plate in a dynamic random access memory which is being fabricated on a silicon wafer.

Abstract: When contact holes are concurrently formed in an inter-level insulating layer over an impurity region in a silicon substrate and a polycide line on a thick field oxide layer, the manufacturer interrupts the etching at the refractory metal silicide layer of the polycide line, and restarts the etching after removal of a part of the refractory metal silicide layer exposed to the short contact hole, thereby preventing the impurity region from undesirable etching for the refractory metal silicide layer.

Abstract: A method of forming a gate metallization in a semiconductor integrated circuit by forming a polycrystalline silicon layer over a gate dielectric layer and then converting the polycrystalline silicon layer into tungsten or tungsten silicide by exposing the polycrystalline silicon to tungsten hexafluoride gas. The method enables the formation of polycrystalline silicon and tungsten or tungsten silicide in the same process cycle in the same reactor or in two similarly configured reactors or in two similarly configured clustered reactors.

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: In order to form a self-aligned damascene gate which enables the resistance of the gate to be reduced, a thick layer of dielectric material is formed over a semiconductor substrate in which drain and source regions have previously been implanted and annealed. The dielectric layer is polished for planarity using a chemical-mechanical-polishing (CMP) technique or the like. A gate mask is then used to pattern the dielectric, the interlayer dielectric (ILD) is etched, and the resist is stripped. A gate dielectric is deposited in the form of a CVD nitride, oxynitride, or stacked nitride oxide ONO, or the like. Polysilicon is then deposited over the dielectric, doped by implantation, and annealed. A silicon rich silicide layer is then deposited after which CMP or the like is used to remove the superfluous portions of the silicide, doped polysilicon and gate oxide layers down to the dielectric level.

Abstract: A first contact hole for a bit line is formed in an interlayer insulating film, and a polysilicon film is formed on the inner surface of the contact hole and on the interlayer insulating film. Subsequently, the polysilicon film is subjected to isotropic dry etching using a resist as a mask, and the interlayer insulating film is subjected to RIE etching, thereby forming a second contact hole in the interlayer insulating film in a peripheral circuit region. Then, a laminated film is formed on the inner surface of the second contact hole and on the polysilicon film, and the second contact hole is filled with a filling member. The laminated film and the polysilicon film are patterned, thereby forming a bit line in a memory cell region.

Abstract: The present invention is directed toward a method for independently doping the gate and the source-drain regions of a semiconductor device. The method is initiated by the provision. of a substrate having isolation regions and a thin insulating layer. Over the substrate is formed a polysilicon layer which is doped with a first type of dopant at a first doping level. Over the polysilicon layer is formed a conducting layer of material that can withstand temperatures of 1000° C., and over the conducting layer is formed a blocking layer. The polysilicon layer, the conducting layer and the blocking layer are etched to form a gate stack. Source-drain regions are subsequently doped with a second type of dopant at a second doping level. Source-drain regions are activated in a 1000° C. heat cycle, and, subsequently, TiSi2 is formed on the source-drain regions. Contacts are then formed.

Abstract: The invention relates to a method of forming a trench filled with a thermally conducting material in a semiconductor substrate. In one embodiment, the method includes filling a portion of the trench with a thermally conducting material and patterning a contact to the thermally conducting material. The invention also relates to a semiconductor device. In one embodiment, the semiconductor device has a trench defining a cell region, wherein a portion of the trench includes a thermally conducting material, and a contact to the thermally conducting material. The invention further relates to a semiconductor device and a method of forming a semiconductor device with an interlayer dielectric that is a thermally conducting material.

Abstract: There is described a method of manufacturing a semiconductor device, wherein a DRAM memory cell and a logic circuit are fabricated on a single semiconductor substrate, which method enables improvements in the refresh characteristics of the DRAM memory cell by preventing a leakage current from developing and enables improvements in the reliability of the semiconductor device, reduces power consumption, and enables improvements in the performance and processing speed of integrated circuits by assembly of the integrated circuits into a single chip. After formation of a polysilicon layer which is to act as gate electrodes, silicon nitride films are formed so as to cover source/drain regions of the DRAM memory cell and to cause other source/drain regions and the polysilicon layer to be exposed. A metal silicide layer is formed on the semiconductor substrate by means of self-aligned silicide technique.