| Class / Patent application number | Description | Number of patent applications / Date published |
|---|
| 257754000 | At least one layer of silicide or polycrystalline silicon | 77 |
| 20080197498 | Gate Electrode Silicidation Process - A fully-silicided gate electrode is formed from silicon and a metal by depositing at least two layers of silicon with the metal layer therebetween. One of the silicon layers may be amorphous silicon whereas the other silicon layer may be polycrystalline silicon. The silicon between the metal layer and the gate dielectric may be deposited in two layers having different crystallinities. This process enables greater control to be exercised over the phase of the silicide resulting from this silicidation process. | 08-21-2008 |
| 20080217779 | SEMICONDUCTOR STRUCTURE AND THE FORMING METHOD THEREOF - The present invention provides a semiconductor structure and the forming method thereof. The structure includes a substrate having a plurality of stacks; a conformal layer on the substrate and a portion of sidewalls of the plurality of the stacks; and a plurality of plugs between the plurality of stacks. In addition, the present invention also provides a method of forming the semiconductor structure, comprising steps of providing a substrate; forming a plurality of stacks on the substrate; forming a conformal layer on the stacks and on the substrate; removing a portion of the conformal layer to expose a sidewall and a top surface of the plurality of stacks; and forming a plurality of plugs between the stacks. | 09-11-2008 |
| 20080217780 | ELIMINATING METAL-RICH SILICIDES USING AN AMORPHOUS Ni ALLOY SILICIDE STRUCTURE - The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films. | 09-11-2008 |
| 20080217781 | ELIMINATING METAL-RICH SILICIDES USING AN AMORPHOUS Ni ALLOY SILICIDE STRUCTURE - The present invention provides a method for producing thin nickel (Ni) monosilicide or NiSi films (having a thickness on the order of about 30 nm or less), as contacts in CMOS devices wherein an amorphous Ni alloy silicide layer is formed during annealing which eliminates (i.e., completely by-passing) the formation of metal-rich silicide layers. By eliminating the formation of the metal-rich silicide layers, the resultant NiSi film formed has improved surface roughness as compared to a NiSi film formed from a metal-rich silicide phase. The method of the present invention also forms Ni monosilicide films without experiencing any dependence of the dopant type concentration within the Si-containing substrate that exists with the prior art NiSi films. | 09-11-2008 |
| 20080224317 | STABLE SILICIDE FILMS AND METHODS FOR MAKING THE SAME - Highly thermally stable metal silicides and methods utilizing the metal silicides in semiconductor processing are provided. The metal silicides are preferably nickel silicides formed by the reaction of nickel with substitutionally carbon-doped single crystalline silicon which has about 2 atomic % or more substitutional carbon. Unexpectedly, the metal silicides are stable to temperatures of about 900° C. and higher and their sheet resistances are substantially unaffected by exposure to high temperatures. The metal silicides are compatible with subsequent high temperature processing steps, including reflow anneals of BPSG. | 09-18-2008 |
| 20080251922 | Transitional Interface between metal and dielectric in interconnect structures - An integrated circuit structure and methods for forming the same are provided. The integrated circuit structure includes a semiconductor substrate; a dielectric layer over the semiconductor substrate; an opening in the dielectric layer; a conductive line in the opening; a metal alloy layer overlying the conductive line; a first metal silicide layer overlying the metal alloy layer; and a second metal silicide layer different from the first metal silicide layer on the first metal silicide layer. The metal alloy layer and the first and the second metal silicide layers are substantially vertically aligned to the conductive line. | 10-16-2008 |
| 20080265420 | METHOD OF FORMING A FULLY SILICIDED SEMICONDUCTOR DEVICE WITH INDEPENDENT GATE AND SOURCE/DRAIN DOPING AND RELATED DEVICE - A method of forming a fully silicided semiconductor device with independent gate and source/drain doping and related device. At least some of the illustrative embodiments are methods comprising forming a gate stack over a substrate (the gate stack comprising a polysilicon layer and a blocking layer), and performing an ion implantation into an active region of the substrate adjacent to the gate stack (the blocking layer substantially blocks the ion implantation from the polysilicon layer). | 10-30-2008 |
| 20080277792 | Semiconductor Device and Method for Manufacturing the Same - Overlapping dummy patterns for a semiconductor device are disclosed. According to an embodiment, a first dummy pattern is formed on a substrate; a second dummy pattern is formed to be overlapped with the first dummy pattern; and a third dummy pattern is formed to provide an electrical connection between the first dummy pattern and the second dummy pattern. | 11-13-2008 |
| 20080303156 | Semiconductor Devices and Methods of Forming Interconnection Lines Therein - An example disclosed semiconductor device includes a semiconductor substrate, a lower interlayer insulating layer formed on the substrate, a lower wire formed on the lower interlayer insulating layer, and an upper interlayer insulating layer which is formed on the lower interlayer insulating layer and has a via hole to expose the lower wire. The lower wire includes a metal layer pattern and a conductive layer pattern, and the metal layer pattern has a protruding portion and the conductive layer pattern is formed on the upper part of the protruding portion of the metal layer pattern and has a hole to expose the protruding portion. | 12-11-2008 |
| 20090008781 | SEMICONDUCTOR DEVICE - A semiconductor device structure includes a substrate, a first conductive layer over the substrate, a second conductive layer between the first conductive layer and the substrate and extending over the sidewalls of the first conductive layer, a dielectric layer between the second conductive layer and the substrate, a cap layer over the first conductive layer and the second conductive layer, and a liner layer on the sidewalls of the second conductive layer. | 01-08-2009 |
| 20090032954 | SEMICONDUCTOR DEVICE AND METHOD OF FABRICATING THE SAME - A semiconductor device includes a first insulation film having a plurality of openings which exposes predetermined regions of a semiconductor substrate, a plurality of first conductive patterns partially filling the openings and a plurality of second conductive patterns disposed on the first conductive patterns within the openings and separated from inner walls of the openings. | 02-05-2009 |
| 20090057906 | Encapsulated silicidation for improved SiC processing and device yield - A method for producing a silicide contact. The method comprises the steps of depositing a metal on a SiC substrate; forming an encapsulating layer on deposited metal; and annealing said deposited metal to form a suicide contact. The encapsulating layer prevents agglomeration and formation of stringers during the annealing process. | 03-05-2009 |
| 20090065940 | METAL WIRING OF A SEMICONDUCTOR DEVICE AND METHOD OF FORMING THE SAME - According to a method of forming a metal wiring of a semiconductor device, a contact plug is formed at height lower than the contact hole, which is formed on an interlayer insulation layer, and then a metal wiring is formed over the contact plug and interlayer insulation layer to completely fill inside of the contact hole, decreasing process difficulty, ensuring reproducibility, and improving electrical property. | 03-12-2009 |
| 20090085213 | SEMICONDUCTOR DEVICE AND METHOD OF FABRICATION - A semiconductor memory device employs a SONOS type memory architecture and includes a bit line diffusion layer in a shallow trench groove in which a conductive film is buried. This makes it possible to decrease the resistivity of the bit line diffusion layer without enlarging the area on the main surface of the semiconductor substrate, and to fabricate the semiconductor memory device having stable electric characteristics without enlarging the cell area. The bit line is formed by implanting ions into the sidewall of Si | 04-02-2009 |
| 20090146306 | Semiconductor device with epitaxial C49-titanium silicide (TiSi2) layer and method for fabricating the same - The present invention relates to a semiconductor device with an epitaxially grown titanium silicide layer having a phase of C49 and a method for fabricating the same. This titanium silicide layer has a predetermined interfacial energy that does not transform the phase of the titanium layer, and thus, occurrences of agglomeration of the titanium layer and a grooving phenomenon can be prevented. The semiconductor device includes: a silicon layer; an insulation layer formed on the silicon layer, wherein a partial portion of the insulation layer is opened to form a contact hole exposing a partial portion of the silicon layer; an epitaxially grown titanium silicide layer having a phase of C49 and formed on the exposed silicon substrate disposed within the contact hole; and a metal layer formed on an upper surface of the titanium silicide layer. | 06-11-2009 |
| 20090166872 | Memory Word lines with Interlaced Metal Layers - A memory device with improved word line structure is disclosed. The memory device includes a plurality of polysilicon strips substantially parallel to each other on the substrate, the plurality of polysilicon strips arranged in two interleaved groups of a first group and a second group. The memory device further includes a first layer of conductive strips forming a plurality of bit lines and a second layer of meal strips, the second layer of conductive strips overlying the polysilicon strips and coupled to the first group of polysilicon strips. In addition, the memory device includes a third layer of conductive strips forming one or more power line, and a fourth layer of metal strips, the fourth layer of conductive strips overlying the second layer of conductive strips and coupled to the second group of polysilicon strips to form a new word line structure having a low resistance. | 07-02-2009 |
| 20090194877 | SEMICONDUCTOR DEVICE HAVING SOI STRUCTURE - A plurality of conductive layers and a plurality of wiring layers connecting a supporting substrate having SOI structure and uppermost wire are formed along a peripheral part of a semiconductor chip together with the uppermost wire, to thereby surround a transistor forming region in which a transistor is to be formed. | 08-06-2009 |
| 20090294968 | SUPPRESSION OF LOCALIZED METAL PRECIPITATE FORMATION AND CORRESPONDING METALLIZATION DEPLETION IN SEMICONDUCTOR PROCESSING - A structure for suppressing localized metal precipitate formation (LMPF) in semiconductor processing. For each metal wire that is exposed to the manufacturing environment and is electrically coupled to an N region, at least one P+ region is formed electrically coupled to the same metal wire. As a result, few excess electrons are available to combine with metal ions to form localized metal precipitate at the metal wire. A monitoring ramp terminal can be formed around and electrically disconnected from the metal wire. By applying a voltage difference to the metal wire and the monitoring ramp terminal and measuring the resulting current flowing through the metal wire and the monitoring ramp terminal, it can be determined whether localized metal precipitate is formed at the metal wire. | 12-03-2009 |
| 20090315182 | SILICIDE INTERCONNECT STRUCTURE - A method for forming an interconnect structure includes forming a dielectric layer above a first layer having a conductive region defined therein. An opening is defined in the dielectric layer to expose at least a portion of the conductive region. A metal silicide is formed in the opening to define the interconnect structure. A semiconductor device includes a first layer having a conductive region defined therein, a dielectric layer formed above the first layer, and a metal silicide interconnect structure extending through the dielectric layer to communicate with the conductive region. | 12-24-2009 |
| 20090315183 | LAYER-STACKED WIRING AND SEMICONDUCTOR DEVICE USING THE SAME - A layer-stacked wiring made up of a microcrystalline silicon thin film and a metal thin film is provided which is capable of suppressing an excessive silicide formation reaction between the microcrystalline silicon thin film and metal thin film, thereby preventing peeling of the thin film. In a polycrystalline silicon TFT (Thin Film Transistor) using the layer-stacked wiring, the microcrystalline silicon thin film is so configured that its crystal grains each having a length of the microcrystalline silicon thin film in a direction of a film thickness being 60% or more of a film thickness of the microcrystalline silicon thin film amount to 15% or less of total number of crystal grains or that its crystal grains each having a length of the microcrystalline silicon thin film in a direction of a film thickness being 50% or less of a film thickness of the microcrystalline silicon thin film amount to 85% or more of the total number of crystal grains making up the microcrystalline silicon thin film. | 12-24-2009 |
| 20100059892 | PRODUCTION METHOD OF SEMICONDUCTOR DEVICE, PRODUCTION METHOD OF DISPLAY DEVICE, SEMICONDUCTOR DEVICE, PRODUCTION METHOD OF SEMICONDUCTOR ELEMENT, AND SEMICONDUCTOR ELEMENT - The present invention provides a production method of a semiconductor device, a production method of a display device, a semiconductor device, a production method of a semiconductor element, and a semiconductor element, each capable of providing a lower-resistance semiconductor element which is more finely prepared through more simple steps. The production method of the semiconductor device of the present invention is a production method of a semiconductor device including a semiconductor element on a substrate, wherein the production method includes a metal silicide-forming step of: transferring the semiconductor element onto the substrate, the semiconductor element having a multilayer structure of a silicon layer and a metal layer, and by heating, forming metal silicide from silicon for a metal layer-side part of the silicon layer and metal for a silicon layer-side part of the metal layer. | 03-11-2010 |
| 20100090343 | Interconnect Structure for Semiconductor Devices - A cap layer for a copper interconnect structure formed in a first dielectric layer is provided. In an embodiment, the cap layer may be formed by an in-situ deposition process in which a process gas comprising germanium, arsenic, tungsten, or gallium is introduced, thereby forming a copper-metal cap layer. In another embodiment, a copper-metal silicide cap is provided. In this embodiment, silane is introduced before, during, or after a process gas is introduced, the process gas comprising germanium, arsenic, tungsten, or gallium. Thereafter, an optional etch stop layer may be formed, and a second dielectric layer may be formed over the etch stop layer or the first dielectric layer. | 04-15-2010 |
| 20100117237 | Silicided Trench Contact to Buried Conductive Layer - A trench contact silicide is formed on an inner wall of a contact trench that reaches to a buried conductive layer in a semiconductor substrate to reduce parasitic resistance of a reachthrough structure. The trench contact silicide is formed at the bottom, on the sidewalls of the trench, and on a portion of the top surface of the semiconductor substrate. The trench is subsequently filled with a middle-of-line (MOL) dielectric. A contact via may be formed on the trench contact silicide. The trench contact silicide may be formed through a single silicidation reaction with a metal layer or through multiple silicidation reactions with multiple metal layers. | 05-13-2010 |
| 20100117238 | METHOD FOR PREPARING A LAYER COMPRISING NICKEL MONOSILICIDE NISI ON A SUBSTRATE COMPRISING SILICON - The invention relates to a method for fabricating a layer comprising nickel monosilicide NiSi on a substrate comprising silicon successively comprising the following steps:
| 05-13-2010 |
| 20100155954 | Methods of forming low interface resistance rare earth metal contacts and structures formed thereby - Methods and associated structures of forming a microelectronic device are described. Those methods may include forming a contact opening in an inter layer dielectric (ILD) disposed on a substrate, wherein a source/drain contact area is exposed, forming a rare earth metal layer on the source/drain contact area, forming a transition metal layer on the rare earth metal layer; and annealing the rare earth metal layer and the transition metal layer to form a metal silicide stack structure. | 06-24-2010 |
| 20100164109 | Backside Metal Treatment of Semiconductor Chips - An integrated circuit structure includes a semiconductor substrate having a front side and a backside. A through-silicon via (TSV) penetrates the semiconductor substrate. The TSV has a back end extending to the backside of the semiconductor substrate. A redistribution line (RDL) is over the backside of the semiconductor substrate and connected to the back end of the TSV. A silicide layer is over and contacting the RDL. | 07-01-2010 |
| 20100176512 | STRUCTURE AND METHOD FOR BACK END OF THE LINE INTEGRATION - An improved semiconductor structure consists of interconnects in an upper interconnect level connected to interconnects in a lower interconnect level through use of a conductive protrusion located at the bottom of a via opening in an upper interconnect level, the conductive protrusion extends upward from bottom of the via opening and into the via opening. The improved interconnect structure with the conductive protrusion between the upper and lower interconnects enhances overall interconnect reliability. | 07-15-2010 |
| 20100181672 | METHOD OF FABRICATING SEMICONDUCTOR DEVICE FOR REDUCING PARASITIC CAPACITANCE BETWEEN BIT LINES AND SEMICONDUCTOR DEVICE FABRICATED THEREBY - In a method of fabricating a semiconductor device capable of reducing parasitic capacitance between bit lines and a semiconductor device fabricated by the method, the semiconductor device includes a semiconductor substrate having buried contact landing pads and direct contact landing pads. A lower interlayer insulating layer is disposed on the semiconductor substrate. A plurality of parallel bit line patterns are disposed on the lower interlayer insulating layer to fill the direct contact holes. A passivation layer that conformally covers the lower interlayer insulating layer and the bit line patterns is formed. An upper interlayer insulating layer for covering the semiconductor substrate having the passivation layer is formed. Buried contact plugs are disposed in the upper interlayer insulating layer between the bit line patterns and extended to contact the respective buried contact landing pads through the passivation layer and the lower interlayer insulating layer. Voids are formed in the upper interlayer insulating layer between the bit line patterns and between the buried contact plugs. | 07-22-2010 |
| 20100181673 | METHOD FOR FABRICATING SEMICONDUCTOR DEVICE AND SEMICONDUCTOR DEVICE - A method for fabricating a semiconductor device, includes forming a dielectric film above a substrate; forming an opening in the dielectric film; forming a first film containing a metal whose energy for forming silicide thereof is lower than that of Cu silicide inside the opening; forming a second film that is conductive and contains copper (Cu) in the opening in which the first film containing the metal is formed; and forming a compound film containing Cu and silicon (Si) selectively on the second film in an atmosphere in which a temperature of the substrate is below 300° C. | 07-22-2010 |
| 20100219531 | METHOD OF FORMING A LOW RESISTANCE SEMICONDUCTOR CONTACT AND STRUCTURE THEREFOR - In one embodiment, silicide layers are formed on two oppositely doped adjacent semiconductor regions. A conductor material is formed electrically contacting both of the two silicides. | 09-02-2010 |
| 20120007243 | METHOD OF MAKING CONNECTIONS IN A BACK-LIT CIRCUIT - A method for forming, on a surface of a thinned-down semiconductor substrate, a contact connected to a metal track of an interconnect stack formed on the opposite surface of the thinned-down substrate, including the steps of: forming, on the side of a first surface of a substrate, an insulating region penetrating into the substrate and coated with a conductive region and with an insulating layer crossed by conductive vias, the vias connecting a metal track of the interconnect stack to the conductive region; gluing the external surface of the interconnect stack on a support and thinning down the substrate; etching the external surface of the thinned-down substrate and stopping on the insulating region; etching the insulating region and stopping on the conductive region; and filling the etched opening with a metal. | 01-12-2012 |
| 20120091589 | METHOD TO ELECTRODEPOSIT NICKEL ON SILICON FOR FORMING CONTROLLABLE NICKEL SILICIDE - The present disclosure relates to an improved method of providing a Ni silicide metal contact on a silicon surface by electrodepositing a Ni film on a silicon substrate. The improved method results in a controllable silicide formation wherein the silicide has a uniform thickness. The metal contacts may be incorporated in, for example, CMOS devices, MEM (micro-electro-mechanical) devices, and photovoltaic cells. | 04-19-2012 |
| 20120104614 | SEMICONDUCTOR DEVICE MANUFACTURING METHOD AND SEMICONDUCTOR DEVICE - A semiconductor device manufacturing method which prevents the resistance of a Ni silicide layer from increasing due to an additive element. First, a reaction control layer which contains a metallic element with an atomic number greater than Ni and does not contain Ni is formed over a silicon layer. Then, Ni is deposited over the reaction control layer and the silicon layer, reaction control layer and Ni are heat-treated to form a Ni silicide layer in the silicon layer. It is preferable that the reaction control layer be comprised of a metallic element with an atomic number greater than Ni. | 05-03-2012 |
| 20120153482 | STRUCTURE AND METHODS OF FORMING CONTACT STRUCTURES - A contact structure and a method of forming the contact structure. The structure includes: a silicide layer on and in direct physical contact with a top substrate surface of a substrate; an electrically insulating layer on the substrate; and an aluminum plug within the insulating layer. The aluminum plug has a thickness not exceeding 25 nanometers in a direction perpendicular to the top substrate surface. The aluminum plug extends from a top surface of the silicide layer to a top surface of the insulating layer. The aluminum plug is in direct physical contact with the top surface of the silicide layer and is in direct physical contact with the silicide layer. The method includes: forming the silicide layer on and in direct physical contact with the top substrate surface of the substrate; forming the electrically insulating layer on the substrate; and forming the aluminum plug within the insulating layer. | 06-21-2012 |
| 20120193796 | POLYSILICON LAYER AND METHOD OF FORMING THE SAME - The method of forming a polysilicon layer is provided. A first polysilicon layer with a first grain size is formed on a substrate. A second polysilicon layer with a second grain size is formed on the first polysilicon layer. The first grain size is smaller than the second grain size. The first polysilicon layer with a smaller grain size can serve as a base for the following deposition, so that the second polysilicon layer formed thereon has a flatter topography, and thus, the surface roughness is reduced and the Rs uniformity within a wafer is improved. | 08-02-2012 |
| 20120280395 | 3-D Integration using Multi Stage Vias - A TSV can be formed having a top section via formed through the top substrate surface and a bottom section via formed through the bottom substrate surface. The top section cross section can have a minimum cross section corresponding to design rules, and the top section depth can correspond to a workable aspect ratio. The top section via can be filled or plugged so that top side processing can be continued. The bottom section via can have a larger cross section for ease of forming a conductive path therethrough. The bottom section via extends from the back side to the bottom of the top section via and is formed after the substrate has been thinned. The TSV is can be completed by forming a conductive path after removing sacrificial fill materials from the joined top and bottom section vias. | 11-08-2012 |
| 20130043592 | Methods of Forming a Replacement Gate Comprised of Silicon and a Device Including Same - Disclosed herein are various methods of forming a replacement gate comprised of silicon and various semiconductor devices incorporation such a replacement gate structure. In one example, the method includes removing a sacrificial gate electrode structure to define a gate opening, forming a replacement gate structure in the gate opening, the replacement gate structure including at least one metal layer and a silicon-containing gate structure that is at least partially made of a metal silicide and forming a protective layer above at least a portion of the replacement gate structure. | 02-21-2013 |
| 20130181350 | SEMICONDUCTOR DEVICES WITH NONCONDUCTIVE VIAS - An electric device with vias that include dielectric structures to prevent conductive material in the vias from electrically connecting conductive structures on a top of the vias with conductive structures on the bottom of the vias. The dielectric structures are formed in selected vias where other vias do not include the dielectric structures. | 07-18-2013 |
| 20130214417 | METHODS OF FORMING A METAL SILICIDE REGION ON AT LEAST ONE SILICON STRUCTURE - A method of forming a metal silicide region. The method comprises forming a metal material over and in contact with exposed surfaces of a dielectric material and silicon structures protruding from the dielectric material. A capping material is formed over and in contact with the metal material. The silicon structures are exposed to heat to effectuate a multidirectional diffusion of the metal material into the silicon structures to form a first metal silicide material. The capping material and unreacted portions of the metal material are removed. The silicon structures are exposed to heat to substantially convert the first metal silicide material into a second metal silicide material. A method of semiconductor device fabrication, an array of silicon structures, and a semiconductor device structure are also described. | 08-22-2013 |
| 20130328199 | SEMICONDUCTOR DEVICE WITH SPACERS FOR CAPPING AIR GAPS AND METHOD FOR FABRICATING THE SAME - A method for fabricating memory device includes forming a bit line pattern including a first conductive layer and a hard mask stacked over a substrate, forming a sacrificial layer on sidewalls of the bit line pattern, forming a second conductive layer in contact with the sacrificial layer and adjacent to the bit line pattern, recessing the second conductive layer, forming an air gap between the recessed second conductive layer and the first conductive layer by removing the sacrificial layer, and forming an air gap capping layer on sidewalls of the hard mask to cap entrance of the air gap. | 12-12-2013 |
| 20140015138 | Leakage Reducing Writeline Charge Protection Circuit - Methods and systems of fabricating a wordline protection structure are described. As described, the wordline protection structure includes a polysilicon structure formed adjacent to a memory core region. The polysilicon structure includes first doped region positioned on a core side of the polysilicon structure and a second doped region positioned on a spine side of the polysilicon structure. An un-doped region positioned between the first and second doped regions. A conductive layer is formed on top of the polysilicon structure and arranged so that it does not contact the un-doped region at either the transition between the first doped region and the un-doped region or the second doped region and un-doped region. | 01-16-2014 |
| 20140027913 | SEMICONDUCTOR STRUCTURES COMPRISING CONDUCTIVE MATERIAL LINING OPENINGS IN AN INSULATIVE MATERIAL - Semiconductor devices have conductive material lining a first opening in an insulative material and in contact with a metal silicide layer at the base of the opening overlying an active area within a silicon material and lining a second opening in the insulative material in direct contact with a polysilicon plug having substantially no metal silicide situated thereon. | 01-30-2014 |
| 20140097541 | Multilayer line trimming - Substantially simultaneous plasma etching of polysilicon and oxide layers in multilayer lines in semiconductors allows for enhanced critical dimensions and aspect ratios of the multilayer lines. Increasing multilayer line aspect ratios may be possible, allowing for increased efficiency, greater storage capacity, and smaller critical dimensions in semiconductor technologies. | 04-10-2014 |
| 20140175653 | SEMICONDUCTOR DEVICES COMPRISING INTERCONNECT STRUCTURES AND METHODS OF FABRICATION - Semiconductor devices comprise at least one integrated circuit layer, at least one conductive trace and an insulative material adjacent at least a portion of the at least one conductive trace. At least one interconnect structure extends through a portion of the at least one conductive trace and a portion of the insulative material, the at least one interconnect structure comprising a transverse cross-sectional dimension through the at least one conductive trace which differs from a transverse cross-sectional dimension through the insulative material. | 06-26-2014 |
| 20140264879 | COPPER-FILLED TRENCH CONTACT FOR TRANSISTOR PERFORMANCE IMPROVEMENT - Methods of fabricating a first contact to a semiconductor device, which fundamentally comprises providing a semiconductor device formed on a substrate. The substrate further includes a conductive surface. A dielectric layer is formed over the substrate and has an opening exposing the conductive surface. The opening extends an entire length of the semiconductor device, partway down the entire length of the device, extending from the device onto adjacent field of the device, or and a combination thereof. A barrier layer is formed within the opening. A copper containing material fills the opening to form a first contact to the semiconductor device. | 09-18-2014 |
| 20150021776 | POLYSILICON LAYER - A polysilicon layer including an amorphous polysilicon layer and a crystallized polysilicon layer is provided. The crystallized polysilicon layer is disposed on the amorphous polysilicon layer. Besides, the amorphous polysilicon layer has a first grain size, the crystallized polysilicon layer has a second grain size, and the first grain size is smaller than the second grain size. The amorphous polysilicon layer with a smaller grain size can serve as a base for the following deposition, so that the crystallized polysilicon layer formed thereon has a flatter topography, and thus, the surface roughness is reduced and the Rs uniformity within a wafer is improved. | 01-22-2015 |
| 20150364416 | SEMICONDUCTOR STRUCTURES HAVING LOW RESISTANCE PATHS THROUGHOUT A WAFER - A semiconductor structure with low resistance conduction paths and methods of manufacture are disclosed. The method includes forming at least one low resistance conduction path on a wafer, and forming an electroplated seed layer in direct contact with the low resistance conduction path. | 12-17-2015 |
| 20160035702 | VERTICALLY INTEGRATED WAFERS WITH THERMAL DISSIPATION - Technologies are generally described related to three-dimensional integration of integrated circuits (ICs) with spacing for heat dissipation. According to some examples, a self-aligned silicide may be formed in a temporary silicon layer and removed subsequent to bonding of the wafers to achieve improved contact between the combined ICs and enhanced heat dissipation through added spacing between the ICs. | 02-04-2016 |
| 20160086888 | SEMICONDUCTOR DEVICE AND METHOD FOR FORMING THE SAME - A semiconductor device includes an active region tilted at an angle with respect to a buried bit line. The buried bit line includes a metal silicide pattern and a metal pattern. The metal silicide pattern has a plurality of metal silicide films each disposed at a lower portion of the active region and corresponding to a bit line contact region. The metal pattern has a plurality of metal films. The metal silicide films and the metal films are alternately arranged and electrically coupled to each other. | 03-24-2016 |
| 20160163648 | Method for Forming an Electrical Contact - A method for forming an electrical contact to a semiconductor structure is provided. The method includes providing a semiconductor structure, providing a metal on an area of said semiconductor structure, wherein said area exposes a semiconductor material and is at least a part of a contact region, converting said metal to a Si-comprising or a Ge-comprising alloy, thereby forming said electrical contact on said area, wherein said converting is done by performing a vapor-solid reaction, whereby said semiconductor structure including said metal is subjected to a silicon-comprising precursor gas or a germanium-comprising precursor gas. | 06-09-2016 |
| 20160379878 | METAL LEVEL FORMATION METHOD AND AN INTEGRATED CIRCUIT STRUCTURE HAVING A METAL LEVEL WITH IMPROVED DIELECTRIC TO METAL ADHESION - Disclosed is a method of forming back end of the line (BEOL) metal levels with improved dielectric capping layer to metal wire adhesion. The method includes process step(s) designed to address dielectric capping layer to metal wire adhesion, when the metal wire(s) in a given metal level are relatively thick. These process step(s) can include, for example: (1) selective adjustment of the deposition tool used to deposit the dielectric capping layer onto metal wires based on the pattern density of the metal wires in order to ensure that those metal wires actually achieve a temperature between 360° C.-400° C.; and/or (2) deposition of a relatively thin dielectric layer on the dielectric capping layer prior to formation of the next metal level in order to reduce the tensile stress of the metal wire(s) below without causing delamination. Also disclosed is an IC chip formed using the above-described method. | 12-29-2016 |
| 20180025988 | SIMULTANEOUS FORMATION OF LINER AND METAL CONDUCTOR | 01-25-2018 |
| 257755000 | Polysilicon laminated with silicide | 4 |
| 20080217782 | METHOD FOR PREPARING 2-DIMENSIONAL SEMICONDUCTOR DEVICES FOR INTEGRATION IN A THIRD DIMENSION - A method which is intended to facilitate and/or simplify the process of fabricating interlayer vias by selective modification of the FEOL film stack on a transfer wafer is provided. Specifically, the present invention provides a method in which two dimensional devices are prepared for subsequent integration in a third dimension at the transition between normal FEOL processes by using an existing interlayer contact mask to define regions in which layers of undesirable dielectrics and metal are selectively removed and refilled with a middle-of-the-line (MOL) compatible dielectric film. As presented, the inventive method is compatible with standard FEOL/MOL integration schemes, and it guarantees a homogeneous dielectric film stack specifically in areas where interlayer contacts are to be formed, thus allowing the option of a straightforward integration path, if desired. | 09-11-2008 |
| 20140061922 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING THE SAME - A semiconductor device includes: a contact hole formed over a structure including a conductive pattern; a contact plug formed in the contact hole; a first metal silicide film surrounding the contact plug; and a second metal silicide film formed over the contact plug. | 03-06-2014 |
| 20140103530 | THREE DIMENSIONAL STACKED SEMICONDUCTOR STRUCTURE AND METHOD FOR MANUFACTURING THE SAME - A three dimensional stacked semiconductor structure comprises a stack including plural oxide layers and conductive layers arranged alternately, at least a contact hole formed vertically to the oxide layers and the conductive layers, and extending to one of the conductive layers, an insulator formed at the sidewall of the contact hole, a conductor formed in the contact hole and connecting the corresponding conductive layer, and the corresponding conductive layer comprises a silicide. The silicide could be formed at edges or an entire body of the corresponding conductive layer. Besides the silicide, the corresponding conductive layer could, partially or completely, further comprise a conductive material connected to the conductor. The corresponding conductive layer which the contact hole extends to has higher conductivity than other conductive layers. Also, the 3D stacked semiconductor structure could be applied to a fan-out region of a 3D flash memory. | 04-17-2014 |
| 20150061136 | SEMICONDUCTOR DEVICES HAVING METAL SILICIDE LAYERS AND METHODS OF MANUFACTURING SUCH SEMICONDUCTOR DEVICES - Provided are a semiconductor device and a method of manufacturing the semiconductor device. In order to improve reliability by solving a problem of conductivity that may occur when an air spacer structure that may reduce a capacitor coupling phenomenon between a plurality of conductive lines is formed, there are provided a semiconductor device including: a substrate having an active region; a contact plug connected to the active region; a landing pad spacer formed to contact a top surface of the contact plug; a contact conductive layer formed to contact the top surface of the contact plug and formed in a space defined by the landing pad spacer; a metal silicide layer formed on the contact conductive layer; and a landing pad connected to the contact conductive layer in a state in which the metal silicide layer is disposed between the landing pad and the contact conductive layer, and a method of manufacturing the semiconductor device. | 03-05-2015 |
| 257756000 | Multiple polysilicon layers | 3 |
| 20090189285 | ON CHIP THERMOCOUPLE AND/OR POWER SUPPLY AND A DESIGN STRUCTURE FOR SAME - A thermocouple and power supply structure. The structure is interleaved through a substrate. The structure includes a first through via extending through the substrate and connected to a first contact on a top surface and a second contact on a bottom surface of the substrate, through via extending through the substrate and connected to the second contact and a third contact on the top surface of the substrate. The first contact, first through via and third contact formed from a first material and the second contact and second through via formed from a second material that is different from the first material. | 07-30-2009 |
| 20100065968 | ELECTRONIC APPARATUS INTERCONNECT ROUTING - Apparatus are provided for routing interconnects of a dual-gate electronic device operating in a differential configuration. An electronic apparatus formed on a substrate is provided comprising a first interconnect ( | 03-18-2010 |
| 20160020211 | Composite Hard Mask Etching Profile for Preventing Pattern Collapse in High-Aspect-Ratio Trenches - High-aspect ratio trenches in integrated circuits are fabricated of composite materials and with trench boundaries having pencil-like etching profiles. The fabrication methods reduce surface tension between trench boundaries and fluids applied during manufacture, thereby avoiding pattern bending, bowing, and collapse. The method, further, facilitates fill-in of trenches with suitable selected materials. | 01-21-2016 |
| 257757000 | Silicide of refractory or platinum group metal | 18 |
| 20080230911 | Method of forming a silicide layer on a thinned silicon wafer, and related semiconducting structure - A semiconducting structure includes a thinned silicon substrate ( | 09-25-2008 |
| 20080237867 | LOW CONTACT RESISTANCE METAL CONTACT - A semiconductor structure and methods of making the same. The semiconductor structure includes a substrate having a suicide region disposed above a doped region, and a metal contact extending through the silicide region and being in direct contact with the doped region. | 10-02-2008 |
| 20080284025 | Electrically Conductive Line - The invention includes an electrically conductive line, methods of forming electrically conductive lines, and methods of reducing titanium silicide agglomeration in the fabrication of titanium silicide over polysilicon transistor gate lines. In one implementation, a method of forming an electrically conductive line includes providing a silicon-comprising layer over a substrate. An electrically conductive layer is formed over the silicon-comprising layer. An MSi | 11-20-2008 |
| 20090001588 | Metal and alloy silicides on a single silicon wafer - Methods and apparatus relating to a single silicon wafer having metal and alloy silicides are described. In one embodiment, two different silicides may be provided on the same wafer. Other embodiments are also disclosed. | 01-01-2009 |
| 20090218695 | LOW CONTACT RESISTANCE METAL CONTACT - A semiconductor structure and methods of making the same. The semiconductor structure includes a substrate having a silicide region disposed above a doped region, and a metal contact extending through the silicide region and being in direct contact with the doped region. | 09-03-2009 |
| 20090267231 | METHOD OF FORMING A SEMICONDUCTOR DEVICE HAVING AN ETCH STOP LAYER AND RELATED DEVICE - In one embodiment, a lower interlayer dielectric layer, and first and second landing pads penetrating the lower interlayer dielectric layer are formed on a substrate. Interconnection patterns covering the second landing pads are formed on the lower interlayer dielectric layer. An etch stop layer is formed over the interconnection patterns. An upper interlayer dielectric layer filling a gap region between the interconnection patterns is formed on the etch stop layer. The upper interlayer dielectric layer is patterned to form a preliminary contact hole between the interconnection patterns, where the etch stop layer is exposed at the bottom of the preliminary contact hole. The preliminary contact hole is extended and the etch stop layer exposed by the extended preliminary contact hole is removed to form a first contact hole exposing the first landing pad. A buried contact plug is then formed within the first contact hole. | 10-29-2009 |
| 20100164110 | METAL SILICIDE NANOWIRES AND METHODS FOR THEIR PRODUCTION - The present invention provides metal silicide nanowires, including metallic, semiconducting, and ferromagnetic semiconducting transition metal silicide nanowires. The nanowires are grown using either chemical vapor deposition (CVD) or chemical vapor transport (CVT) on silicon substrates covered with a thin silicon oxide film, the oxide film desirably having a thickness of no greater than about 5 nm and, desirably, no more than about 2 nm (e.g., about 1-2 nm). The metal silicide nanowires and heterostructures made from the nanowires are well-suited for use in CMOS compatible wire-like electronic, photonic, and spintronic devices. | 07-01-2010 |
| 20110227227 | INTEGRATED CIRCUIT HAVING TSVS INCLUDING HILLOCK SUPPRESSION - A method for fabricating integrated circuit (ICs) having through substrate vias (TSVs) includes forming active circuit elements on a semiconductor wafer and then forming a plurality of embedded vias through the top side of the wafer. A metal filler layer including a filler metal is deposited to fill the embedded vias. Chemical mechanical polishing (CMP) then forms a plurality of embedded TSVs that have polished top TSV surfaces having exposed filler metal. An electrically conductive hillock suppression structure is formed by forming a silicon or germanium doped region, or a silicide or germanicide at the polished top TSV surface or by forming a metal layer on the polished top TSV surface having a composition different from the filler metal. A dielectric layer is deposited on the semiconductor wafer including over the hillock suppression structure. The dielectric layer is removed over the polished top TSV surface to allow metal contact thereto. | 09-22-2011 |
| 20110278726 | METHOD OF FORMING A SEMICONDUCTOR DEVICE HAVING AN ETCH STOP LAYER AND RELATED DEVICE - In one embodiment, a lower interlayer dielectric layer, and first and second landing pads penetrating the lower interlayer dielectric layer are formed on a substrate. Interconnection patterns covering the second landing pads are formed on the lower interlayer dielectric layer. An etch stop layer is formed over the interconnection patterns. An upper interlayer dielectric layer filling a gap region between the interconnection patterns is formed on the etch stop layer. The upper interlayer dielectric layer is patterned to form a preliminary contact hole between the interconnection patterns, where the etch stop layer is exposed at the bottom of the preliminary contact hole. The preliminary contact hole is extended and the etch stop layer exposed by the extended preliminary contact hole is removed to form a first contact hole exposing the first landing pad. A buried contact plug is then formed within the first contact hole. | 11-17-2011 |
| 20120161324 | Semiconductor Device Comprising Contact Elements with Silicided Sidewall Regions - When forming a metal silicide within contact openings in complex semiconductor devices, a silicidation of sidewall surface areas of the contact openings may be initiated by forming a silicon layer therein, thereby reducing unwanted diffusion of the refractory metal species into the laterally adjacent dielectric material. In this manner, superior reliability and electrical performance of the resulting contact elements may be achieved on the basis of a late silicide process. | 06-28-2012 |
| 20120235301 | SEMICONDUCTOR APPARATUS - A method of integrated circuit fabrication is provided, and more particularly fabrication of a semiconductor apparatus with a metallic alloy. An exemplary structure for a semiconductor apparatus comprises a first silicon substrate having a first contact comprising a silicide layer between the substrate and a first metal layer; a second silicon substrate having a second contact comprising a second metal layer; and a metallic alloy between the first metal layer of the first contact and the second metal layer of the second contact. | 09-20-2012 |
| 20130320543 | SEMICONDUCTOR DEVICE MANUFACTURING METHOD AND SEMICONDUCTOR DEVICE - A semiconductor device is manufactured by forming, on an insulating base material, a first support element having a side face that extends from a surface of the insulating base material, forming a coating of amorphous silicon on the side face of the first support element, filling an aperture disposed between the first support element and a second support element that extends from a surface of the insulating base material with an insulating film, planarizing the insulating film to expose an exposed portion of the coating and a surface of the first support element, and siliciding the amorphous silicon of the coating to form an interconnect. | 12-05-2013 |
| 20140284801 | SEMICONDUCTOR DEVICE AND METHOD FOR MANUFACTURING SAME - According to an embodiment, a semiconductor device, includes a substrate, an inter-layer insulating layer provided above the substrate, a first interconnect provided in a first trench, and a second interconnect provided in a second trench. The first interconnect is made of a first metal, and the first trench is provided in the inter-layer insulating layer on a side opposite to the substrate. The second interconnect is made of a second metal, and the second trench is provided in the inter-layer insulating layer toward the substrate. A width of the second trench is wider than a width of the first trench. A mean free path of electrons in the first metal is shorter than a mean free path of electrons in the second metal, and the first metal is a metal, an alloy or a metal compound, including at least one nonmagnetic element as a constituent element. | 09-25-2014 |
| 20150325668 | SEMICONDUCTOR DEVICE AND METHOD FOR FABRICATING THE SAME - Provided is a method for fabricating a semiconductor device including the following steps. A silicon-containing conductive layer is formed on a substrate. Then, a dielectric layer is formed around the silicon-containing conductive layer. A portion of the dielectric layer is removed to expose a first sidewall of the silicon-containing conductive layer. A shielding structure is formed on a partial surface of the silicon-containing conductive layer, and the shielding structure exposes at least the first sidewall. A metal layer is formed on the substrate to cover the silicon-containing conductive layer not covered by the shielding structure. A salicide process is performed to form a silicide layer. | 11-12-2015 |
| 20150371952 | SEMICONDUCTOR CONTACT WITH DIFFUSION-CONTROLLED IN SITU INSULATOR FORMATION - A contact is created by forming a layer of dielectric material on a silicon-containing region of a semiconductor substrate. An opening is created through the layer of dielectric material, the opening having a bottom and exposing the silicon-containing region. An oxygen-containing layer is formed on type of the semiconductor substrate. A metal stack is formed within the opening and includes a first metal film with a first type of metal and a second type of metal and a second metal film. The metal stack, the oxygen-containing layer and the silicon-containing region of the semiconductor substrate are annealed to form a metallic oxide layer and a metal silicide layer. A first liner is formed within the opening. A fill metal is deposited in the opening. | 12-24-2015 |
| 20160027889 | DIFFUSION-CONTROLLED OXYGEN DEPLETION OF SEMICONDUCTOR CONTACT INTERFACE - A device is created by forming a layer of dielectric material on a silicon-containing region of a semiconductor substrate. An opening is created through the layer of dielectric material, the opening having a bottom and exposing the silicon-containing region. A metal stack is formed within the opening. The metal stack includes at least a first metal film on the silicon-containing region and a second gettering metal film on the first metal film. The metal stack is annealed to cause oxygen to migrate from the substrate to the gettering metal film. A first liner is formed within the opening. A fill metal is deposited in the opening. | 01-28-2016 |
| 20160111369 | NOVEL SEMICONDUCTOR SYSTEM AND DEVICE - A 3D IC device including: a first semiconductor layer including first mono-crystallized transistors, where the first mono-crystallized transistors are interconnected by at least one metal layer including aluminum or copper; a second layer including second mono-crystallized transistors and overlaying the at least one metal layer, where the at least one metal layer is in-between the first semiconductor layer and the second layer; a global power grid to distribute power to the device overlaying the second layer; and a local power grid to distribute power to the first mono-crystallized transistors, where the global power grid is connected to the local power grid by a plurality of through second layer vias, and where the vias have a radius of less than 150 nm. | 04-21-2016 |
| 20160181383 | SEMICONDUCTOR DEVICE AND MANUFACTURING METHOD THEREOF | 06-23-2016 |
