| Patent application number | Description | Published |
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| 20080213159 | Nanotube separation methods - A nanotube separation method includes depositing a tag on a nanotube in a nanotube mixture. The nanotube has a defect and the tag deposits at the defect where a deposition rate is greater than on another nanotube in the mixture lacking the defect. The method includes removing the tagged nanotube from the mixture by using the tag. As one option, the tag may contain a ferromagnetic material and the removing may include applying a magnetic field. As another option, the tag may contain an ionic material and the removing may include applying an electric field. As a further option, the tag may contain an atom having an atomic mass greater than the atomic mass of carbon and the removing may include applying a centrifugal force to the nanotube mixture. Any two or more of the indicated removal techniques may be combined. | 09-04-2008 |
| 20080220600 | Semiconductor constructions, methods of forming multiple lines, and methods of forming high density structures and low density structures with a single photomask - Some embodiments include formation of polymer spacers along sacrificial material, removal of the sacrificial material, and utilization of the polymer spacers as masks during fabrication of integrated circuitry. The polymer spacer masks may, for example, be utilized to pattern flash gates of a flash memory array. In some embodiments, the polymer is simultaneously formed across large sacrificial structures and small sacrificial structures. The polymer is thicker across the large sacrificial structures than across the small sacrificial structures, and such difference in thickness is utilized to fabricate high density structures and low-density structures with a single photomask. | 09-11-2008 |
| 20080237601 | TRANSISTORS AND SEMICONDUCTOR CONSTRUCTIONS - A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing. Preferably, the annealing temperature is both sufficiently high to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries, but sufficiently low to prevent chemical reaction of the fluorine containing layer with the polycrystalline thin film layer. | 10-02-2008 |
| 20080241386 | Atomic Layer Deposition Methods - The invention includes an atomic layer deposition method of forming a layer of a deposited composition on a substrate. The method includes positioning a semiconductor substrate within an atomic layer deposition chamber. On the substrate, an intermediate composition monolayer is formed, followed by a desired deposited composition from reaction with the intermediate composition, collectively from flowing multiple different composition deposition precursors to the substrate within the deposition chamber. A material adheres to a chamber internal component surface from such sequentially forming. After such sequentially forming, a reactive gas flows to the chamber which is different in composition from the multiple different deposition precursors and which is effective to react with such adhering material. After the reactive gas flowing, such sequentially forming is repeated. Further implementations are contemplated. | 10-02-2008 |
| 20080258057 | Integrated circuit chips, apparatuses for obtaining backscatter data from samples, methods of backscatter analysis, and methods of forming alpha particle emission and detection systems - Some embodiments include methods for fabricating an alpha particle emitter and detector associated with an integrated circuit chip. Some embodiments include an integrated circuit chip comprising an alpha particle emitter and detector supported by a semiconductor substrate. Some embodiments include an apparatus for obtaining backscatter data from a sample utilizing an alpha particle emission and detection system supported by a semiconductor substrate. Some embodiments include methods of backscatter analysis utilizing a semiconductor substrate containing an alpha particle emitter and an alpha particle sensor. | 10-23-2008 |
| 20080286699 | Reticles, and methods of treating reticles, configuring reticles and using reticles - Some embodiments include methods of treating reticles to provide backside masking across regions of the reticle to compensate for problems occurring during photolithographic processing. The problems may be, for example, defects in the reticle, problems associated with deposition or development of photoresist, or problems associated with substrate topography. The masking may alter one or both of transmission of electromagnetic radiation through the masked regions, and polarization of electromagnetic radiation passed through the masked regions. Some embodiments include reticles having patterns along front sides for patterning electric magnetic radiation, and masks across portions of the backsides to at least partially block transmission of electromagnetic radiation through portions of the patterns. | 11-20-2008 |
| 20080303084 | Vertical Tunneling Transistor - The disclosed embodiments relate to a vertical tunneling transistor that may include a channel disposed on a substrate. A quantum dot may be disposed so that an axis through the channel and the quantum dot is substantially perpendicular to the substrate. A gate may be disposed so that an axis through the channel, the quantum dot and the gate is substantially perpendicular to the substrate. | 12-11-2008 |
| 20090011607 | Silicon Dioxide Deposition Methods Using at Least Ozone and TEOS as Deposition Precursors - Embodiments disclosed herein pertain to silicon dioxide deposition methods using at least ozone and tetraethylorthosilicate (TEOS) as deposition precursors. In one embodiment, a silicon dioxide deposition method using at least ozone and TEOS as deposition precursors includes flowing precursors comprising ozone and TEOS to a substrate under subatmospheric pressure conditions effective to deposit silicon dioxide-comprising material having an outer surface onto the substrate. The outer surface is treated effective to one of add hydroxyl to or remove hydroxyl from the outer surface in comparison to any hydroxyl presence on the outer surface prior to said treating. After the treating, precursors comprising ozone and TEOS are flowed to the substrate under subatmospheric pressure conditions effective to deposit silicon dioxide-comprising material onto the treated outer surface of the substrate. Other embodiments are contemplated. | 01-08-2009 |
| 20090044610 | SYSTEMS AND METHODS FOR CHARACTERIZING THICKNESS AND TOPOGRAPHY OF MICROELECTRONIC WORKPIECE LAYERS - Metrology systems, tools, and methods that characterize one or more layers of a microelectronic workpiece are disclosed herein. In one embodiment, a system for characterizing thickness and topography of a workpiece layer includes a layer thickness instrument configured to measure a thickness of a first workpiece layer at individual sampling sites, a surface topography instrument configured to measure a relative surface height of the first layer at the individual sampling sites, and a processing unit communicatively coupled to receive thickness and topography measurements and operable to output layer data that includes individual thickness measurements combined with individual topography measurements at workpiece coordinates corresponding to the individual sampling sites. In another embodiment, the system further includes an output device communicatively coupled with the processing unit and operable to graphically display a stratigraphic cross-section corresponding to the output layer data. | 02-19-2009 |
| 20090047776 | Method of Forming a Thin Film Transistor - A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing. Preferably, the annealing temperature is both sufficiently high to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries, but sufficiently low to prevent chemical reaction of the fluorine containing layer with the polycrystalline thin film layer. | 02-19-2009 |
| 20090056746 | Methods For Treating Surfaces, And Apparatuses For Treating Surfaces - Some embodiments include methods of treating surfaces with aerosol particles. The aerosol particles may be formed as liquid particles, and then passed through a chamber under conditions which change the elasticity of the particles prior to impacting a surface with the particles. The change in elasticity may be an increase in the elasticity, or a decrease in the elasticity. The change in elasticity may be accomplished by causing a phase change of one or more components of the aerosol particles such as, for example, by at least partially freezing the aerosol particles, or by forming entrained bubbles within the aerosol particles. Some embodiments include apparatuses that may be utilized during treatment of surfaces with aerosol particles. | 03-05-2009 |
| 20090061107 | Formation of Carbon-Containing Material - A method includes forming ionic clusters of carbon-containing molecules, which molecules have carbon-carbon sp | 03-05-2009 |
| 20090065026 | Methods For Treating Surfaces, Methods For Removing One Or More Materials from Surfaces, And Apparatuses For Treating Surfaces - Some embodiments include utilization of both plasma and aerosol to treat substrate surfaces. The plasma and aerosol may be utilized simultaneously, or sequentially. In some embodiments, the plasma forms a plasma sheath over the substrate surfaces, with the plasma sheath having an electric field gradient therein. The aerosol comprises liquid particles charged to a polarity, and such polarity is transferred to contaminants on the substrate surfaces through interaction with the aerosol. The polarity may be used to assist in dislodging the contaminants from the substrate surfaces. The electric field of the plasma sheath may then sweep the contaminants away from the substrate surfaces. In some embodiments, multiple different aerosols are formed to remove multiple different types of materials from substrate surfaces. Some embodiments include apparatuses configured for treating substrate surfaces with both plasma and aerosol. | 03-12-2009 |
| 20090090692 | Methods of Processing Substrates and Methods of Forming Conductive Connections to Substrates - Embodiments disclosed include methods of processing substrates, including methods of forming conductive connections to substrates. In one embodiment, a method of processing a substrate includes forming a material to be etched over a first material of a substrate. The material to be etched and the first material are of different compositions. The material to be etched is etched in a dry etch chamber to expose the first material. After the etching, the first material is contacted with a non-oxygen-containing gas in situ within the dry etch chamber effective to form a second material physically contacting onto the first material. The second material comprises a component of the first material and a component of the gas. In one embodiment, the first material is contacted with a gas that may or may not include oxygen in situ within the dry etch chamber effective to form a conductive second material. | 04-09-2009 |
| 20090114246 | Methods For Treating Surfaces - Some embodiments include methods for treating surfaces. Beads and/or other insolubles may be dispersed within a liquid carrier to form a dispersion. A transfer layer may be formed across a surface. The dispersion may be directed toward the transfer layer, and the insolubles may impact the transfer layer. The impacting may generate force in the transfer layer, and such force may be transferred through the transfer layer to the surface. The surface may be a surface of a semiconductor substrate, and the force may be utilized to sweep contaminants from the semiconductor substrate surface. The transfer layer may be a liquid, and in some embodiments may be a cleaning solution. | 05-07-2009 |
| 20090122486 | Semiconductor Packages - The invention includes semiconductor packages having grooves within a semiconductor die backside; and includes semiconductor packages utilizing carbon nanostructures (such as, for example, carbon nanotubes) as thermally conductive interface materials. The invention also includes methods of cooling a semiconductor die in which coolant is forced through grooves in a backside of the die, and includes methods of making semiconductor packages. | 05-14-2009 |
| 20090134443 | FLOATING-GATE STRUCTURE WITH DIELECTRIC COMPONENT - Floating-gate memory cells having a floating gate with a conductive portion and a dielectric portion facilitate increased levels of charge trapping sites within the floating gate. The conductive portion includes a continuous component providing bulk conductivity to the floating gate. The dielectric portion is discontinuous within the conductive portion and may include islands of dielectric material and/or one or more contiguous layers of dielectric material having discontinuities. | 05-28-2009 |
| 20090149026 | METHOD FOR FORMING HIGH DENSITY PATTERNS - Methods are disclosed, such as those involving increasing the density of isolated features in an integrated circuit. In one or more embodiments, a method is provided for forming an integrated circuit with a pattern of isolated features having a final density of isolated features that is greater than a starting density of isolated features in the integrated circuit by a multiple of two or more. The method can include forming a pattern of pillars having a density X, and forming a pattern of holes amongst the pillars, the holes having a density at least X. The pillars can be selectively removed to form a pattern of holes having a density at least 2X. In some embodiments, plugs can be formed in the pattern of holes, such as by epitaxial deposition on the substrate, in order to provide a pattern of pillars having a density 2X. In other embodiments, the pattern of holes can be transferred to the substrate by etching. | 06-11-2009 |
| 20090161438 | METHODS OF FORMING AND PROGRAMMING FLOATING-GATE MEMORY CELLS HAVING CARBON NANOTUBES - Floating-gate memory cells having carbon nanotubes interposed between the substrate and the tunnel dielectric layer facilitate ballistic injection of charge into the floating gate. The carbon nanotubes may extend across the entire channel region or a portion of the channel region. For some embodiments, the carbon nanotubes may be concentrated near the source/drain regions. For some embodiments, the tunnel dielectric layer may adjoin the substrate in at least a portion of the channel region. | 06-25-2009 |
| 20090180324 | Semiconductor Constructions, NAND Unit Cells, Methods Of Forming Semiconductor Constructions, And Methods Of Forming NAND Unit Cells - Some embodiments include methods of forming semiconductor constructions. Alternating layers of n-type doped material and p-type doped material may be formed. The alternating layers may be patterned into a plurality of vertical columns that are spaced from one another by openings. The openings may be lined with tunnel dielectric, charge-storage material and blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed within the lined openings. Some embodiments include methods of forming NAND unit cells. Columns of alternating n-type material and p-type material may be formed. The columns may be lined with a layer of tunnel dielectric, a layer of charge-storage material, and a layer of blocking dielectric. Alternating layers of insulative material and conductive control gate material may be formed between the lined columns. Some embodiments include semiconductor constructions, and some embodiments include NAND unit cells. | 07-16-2009 |
| 20090203206 | FABRICATION OF SEMICONDUCTOR DEVICES USING ANTI-REFLECTIVE COATINGS - Techniques are disclosed for fabricating a device using a photolithographic process. The method includes providing a first anti-reflective coating over a surface of a substrate. A layer which is transparent to a wavelength of light used during the photolithographic process is provided over the first anti-reflective coating, and a photosensitive material is provided above the transparent layer. The photosensitive material is exposed to a source of radiation including the wavelength of light. Preferably, the first anti-reflective coating extends beneath substantially the entire transparent layer. The complex refractive index of the first anti-reflective coating can be selected to maximize the absorption at the first anti-reflective coating to reduce notching of the photosensitive material. | 08-13-2009 |
| 20090209080 | Methods of Forming Pluralities of Capacitors - The invention includes methods of forming pluralities of capacitors. In one implementation, a method of forming a plurality of capacitors includes providing a plurality of capacitor electrodes within a capacitor array area over a substrate. The capacitor electrodes comprise outer lateral sidewalls. The plurality of capacitor electrodes is supported at least in part with a retaining structure which engages the outer lateral sidewalls. The retaining structure is formed at least in part by etching a layer of material which is not masked anywhere within the capacitor array area to form said retaining structure. The plurality of capacitor electrodes is incorporated into a plurality of capacitors. Other aspects and implementations are contemplated. | 08-20-2009 |
| 20090215253 | Method of Forming a Nitrogen-Enriched Region within Silicon-Oxide-Containing Masses - The invention encompasses a method of incorporating nitrogen into a silicon-oxide-containing layer. The silicon-oxide-containing layer is exposed to a nitrogen-containing plasma to introduce nitrogen into the layer. The nitrogen is subsequently thermally annealed within the layer to bond at least some of the nitrogen to silicon within the layer. The invention also encompasses a method of forming a transistor. A gate oxide layer is formed over a semiconductive substrate. The gate oxide layer comprises silicon dioxide. The gate oxide layer is exposed to a nitrogen-containing plasma to introduce nitrogen into the layer, and the layer is maintained at less than or equal to 400° C. during the exposing. Subsequently, the nitrogen within the layer is thermally annealed to bond at least a majority of the nitrogen to silicon. At least one conductive layer is formed over the gate oxide layer. Source/drain regions are formed within the semiconductive substrate, and are gatedly connected to one another by the at least one conductive layer. The invention also encompasses transistor structures. | 08-27-2009 |
| 20090252946 | METHOD FOR PURIFICATION OF SEMICONDUCTING SINGLE WALL NANOTUBES - A process of forming a semiconductive carbon nanotube structure includes imposing energy on a mixture that contains metallic carbon nanotubes and semiconductive carbon nanotubes under conditions to cause the metallic carbon nanotubes to be digested or to decompose so that they may be separated away from the semiconductive carbon nanotubes. | 10-08-2009 |
| 20090253271 | SPIN-ON FILM PROCESSING USING ACCOUSTIC RADIATION PRESSURE - An apparatus and process operate to impose sonic pressure upon a spin-on film liquid mass that exhibits a liquid topography and in a solvent vapor overpressure to alter the liquid topography. Other apparatus and processes are disclosed. | 10-08-2009 |
| 20090263962 | NON-VOLATILE MEMORY CELL DEVICE AND METHODS - A method of fabricating a memory cell including forming nanodots over a first dielectric layer and forming a second dielectric layer over the nanodots, where the second dielectric layer encases the nanodots. In addition, an intergate dielectric layer is formed over the second dielectric layer. To form sidewalls of the memory cell, a portion of the intergate dielectric layer and a portion of the second dielectric layer are removed with a dry etch, where the sidewalls include a location where a nanodot has been deposited. A spacing layer is formed over the sidewalls to cover the location where a nanodot has been deposited and the remaining portion of the second dielectric layer and the nanodots can be removed with an isotropic etch selective to the second dielectric layer. | 10-22-2009 |
| 20090288603 | PLASMA AND ELECTRON BEAM ETCHING DEVICE AND METHOD - Methods and devices for selective etching in a semiconductor process are shown. Chemical species generated in a reaction chamber provide both a selective etching function and concurrently form a protective coating on other regions. An electron beam provides activation to selective chemical species. In one example, reactive species are generated from a plasma source to provide an increased reactive species density. Addition of other gasses to the system can provide functions such as controlling a chemistry in a protective layer during a processing operation. | 11-26-2009 |
| 20090294878 | CIRCUITRY AND GATE STACKS - The present invention includes semiconductor circuitry. Such circuitry encompasses a metal silicide layer over a substrate and a layer comprising silicon, nitrogen and oxygen in physical contact with the metal silicide layer. The present invention also includes a gate stack which encompasses a polysilicon layer over a substrate, a metal silicide layer over the polysilicon layer, an antireflective material layer over the metal silicide layer, a silicon nitride layer over the antireflective material layer, and a layer of photoresist over the silicon nitride layer, for photolithographically patterning the layer of photoresist to form a patterned masking layer from the layer of photoresist and transferring a pattern from the patterned masking layer to the silicon nitride layer, antireflective material layer, metal silicide layer and polysilicon layer. The patterned silicon nitride layer, antireflective material layer, metal silicide layer and polysilicon layer encompass a gate stack. | 12-03-2009 |
| 20090294967 | Diodes, And Methods Of Forming Diodes - Some embodiments include methods of forming diodes. The methods may include oxidation of an upper surface of a conductive electrode to form an oxide layer over the conductive electrode. In some embodiments, the methods may include formation of an oxidizable material over a conductive electrode, and subsequent oxidation of the oxidizable material to form an oxide layer over the conductive electrode. In some embodiments, the methods may include formation of a metal halide layer over a conductive electrode. Some embodiments include diodes that contain a metal halide layer between a pair of diode electrodes. | 12-03-2009 |
| 20090302322 | Method of Forming a Thin Film Transistor - A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing. Preferably, the annealing temperature is both sufficiently high to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries, but sufficiently low to prevent chemical reaction of the fluorine containing layer with the polycrystalline thin film layer. | 12-10-2009 |
| 20090309151 | Semiconductor Constructions - Some embodiments include methods of forming flash memory cells and semiconductor constructions, and some embodiments include semiconductor constructions. Some embodiments may include a method in which a semiconductor substrate is provided to have a plurality of active area locations. Floating gates are formed over the active area locations, with the floating gates having widths that are entirely sub-lithographic. Adjacent floating gates are spaced from one another by gaps. Dielectric material and control gate material are formed over the floating gates and within the gaps. Some embodiments may include a construction in which a pair of adjacent floating gates are over a pair of adjacent active areas, with the floating gates being spaced from one another by a distance which is greater than a distance that the active areas are spaced from one another. | 12-17-2009 |
| 20090315020 | Diodes, and Methods of Forming Diodes - Some embodiments include methods of forming diodes in which a first electrode is formed to have a pedestal extending upwardly from a base. At least one layer is deposited along an undulating topography that extends across the pedestal and base, and a second electrode is formed over the least one layer. The first electrode, at least one layer, and second electrode together form a structure that conducts current between the first and second electrodes when voltage of one polarity is applied to the structure, and that inhibits current flow between the first and second electrodes when voltage having a polarity opposite to said one polarity is applied to the structure. Some embodiments include diodes having a first electrode that contains two or more projections extending upwardly from a base, having at least one layer over the first electrode, and having a second electrode over the at least one layer. | 12-24-2009 |
| 20090316126 | HIGH RESOLUTION PRINTING TECHNIQUE - A pattern having exceptionally small features is printed on a partially fabricated integrated circuit during integrated circuit fabrication. The pattern is printed using an array of probes, each probe having: 1) a photocatalytic nanodot at its tip; and 2) an individually controlled light source. The surface of the partially fabricated integrated circuit comprises a photochemically active species. The active species undergoes a chemical change when contacted by the nanodot, when the nanodot is illuminated by light. To print a pattern, each probe raster-scans its associated nanodot across the surface of the partially fabricated integrated circuit. When the nanodot reaches a desired location, the nanodot is illuminated by the light source, catalyzing a change in the reactive species and, thus, printing at that location. Subsequently, reacted or unreacted species are selectively removed, thereby forming a mask pattern over the partially fabricated integrated circuit. The minimum size of the features in the pattern is determined by the size of the nanodot and can be very small, e.g., having critical dimensions of about 20 nm or less. | 12-24-2009 |
| 20100012922 | METHODS OF FORMING STRUCTURES INCLUDING NANOTUBES AND STRUCTURES INCLUDING SAME - A semiconductor structure including nanotubes forming an electrical connection between electrodes is disclosed. The semiconductor structure may include an open volume defined by a lower surface of an electrically insulative material and sidewalls of at least a portion of each of a dielectric material and opposing electrodes. The nanotubes may extend between the opposing electrodes, forming a physical and electrical connection therebetween. The nanotubes may be encapsulated within the open volume in the semiconductor structure. A semiconductor structure including nanotubes forming an electrical connection between source and drain regions is also disclosed. The semiconductor structure may include at least one semiconducting carbon nanotube electrically connected to a source and a drain, a dielectric material disposed over the at least one semiconducting carbon nanotube and a gate dielectric overlying a portion of the dielectric material. Methods of forming the semiconductor structures are also disclosed. | 01-21-2010 |
| 20100013107 | INTERCONNECT STRUCTURES FOR INTEGRATION OF MULTI-LAYERED INTEGRATED CIRCUIT DEVICES AND METHODS FOR FORMING THE SAME - 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. Methods of forming semiconductor devices comprising at least one interconnect structure are also disclosed. | 01-21-2010 |
| 20100038730 | SEMICONDUCTOR STRUCTURES INCLUDING A MOVABLE SWITCHING ELEMENT, SYSTEMS INCLUDING SAME AND METHODS OF FORMING SAME - Semiconductor structures including a movable switching element having a base disposed on a conductive pad, a body extending from the base, and an end laterally adjacent and spaced apart from a conductive contact are disclosed. Upon application of a threshold voltage, the movable switching element may deform toward the conductive contact via an electrical field, establishing electrical contact between the conductive pad and the conductive contact. Various methods may be used to form such semiconductor structures, and switching devices including such semiconductor structures. Memory devices and electronic systems include such switching devices. | 02-18-2010 |
| 20100047945 | Methods Of Forming Particle-Containing Materials - The invention includes methods of forming particle-containing materials, and also includes semiconductor constructions comprising particle-containing materials. One aspect of the invention includes a method in which a first monolayer is formed across at least a portion of a semiconductor substrate, particles are adhered to the first monolayer, and a second monolayer is formed over the particles. Another aspect of the invention includes a construction containing a semiconductor substrate and a particle-impregnated conductive material over at least a portion of the semiconductor substrate. The particle-impregnated conductive material can include tungsten-containing particles within a layer which includes tantalum or tungsten. | 02-25-2010 |
| 20100091574 | ONE-TRANSISTOR COMPOSITE-GATE MEMORY - One-transistor memory devices facilitate nonvolatile data storage through the manipulation of oxygen vacancies within a trapping layer of a field-effect transistor (FET), thereby providing control and variation of threshold voltages of the transistor. Various threshold voltages may be assigned a data value, providing the ability to store one or more bits of data in a single memory cell. To control the threshold voltage, the oxygen vacancies may be manipulated by trapping electrons within the vacancies, freeing trapped electrons from the vacancies, moving the vacancies within the trapping layer and annihilating the vacancies. | 04-15-2010 |
| 20100092890 | METHOD TO ALIGN MASK PATTERNS - Alignment tolerances between narrow mask lines, for forming interconnects in the array region of an integrated circuit, and wider mask lines, for forming interconnects in the periphery of the integrated circuit, are increased. The narrow mask lines are formed by pitch multiplication and the wider mask lines are formed by photolithography. The wider mask lines and are aligned so that one side of those lines is flush with or inset from a corresponding side of the narrow lines. Being wider, the opposite sides of the wider mask lines protrude beyond the corresponding opposite sides of the narrow mask lines. The wider mask lines are formed in negative photoresist having a height less than the height of the narrow mask lines. Advantageously, the narrow mask lines can prevent expansion of the mask lines in one direction, thus increasing alignment tolerances in that direction. In the other direction, use of photolithography and a shadowing effect caused by the relative heights of the photoresist and the narrow mask lines causes the wider mask lines to be formed with a rounded corner, thus increasing alignment tolerances in that direction by increasing the distance to a neighboring narrow mask line. | 04-15-2010 |
| 20100092891 | PITCH REDUCED PATTERNS RELATIVE TO PHOTOLITHOGRAPHY FEATURES - Differently-sized features of an integrated circuit are formed by etching a substrate using a mask which is formed by combining two separately formed patterns. Pitch multiplication is used to form the relatively small features of the first pattern and conventional photolithography used to form the relatively large features of the second pattern. Pitch multiplication is accomplished by patterning a photoresist and then etching that pattern into an amorphous carbon layer. Sidewall spacers are then formed on the sidewalls of the amorphous carbon. The amorphous carbon is removed, leaving behind the sidewall spacers, which define the first mask pattern. A bottom anti-reflective coating (BARC) is then deposited around the spacers to form a planar surface and a photoresist layer is formed over the BARC. The photoresist is next patterned by conventional photolithography to form the second pattern, which is then is transferred to the BARC. The combined pattern made out by the first pattern and the second pattern is transferred to an underlying amorphous silicon layer and the pattern is subjected to a carbon strip to remove BARC and photoresist material. The combined pattern is then transferred to the silicon oxide layer and then to an amorphous carbon mask layer. The combined mask pattern, having features of difference sizes, is then etched into the underlying substrate through the amorphous carbon hard mask layer. | 04-15-2010 |
| 20100093175 | Methods Of Forming Patterns Utilizing Lithography And Spacers - Some embodiments include methods of forming patterns. A first set of features is photolithographically formed over a substrate, and then a second set of features is photolithographically formed over the substrate. At least some of the features of said second set alternate with features of the first set. Spacer material is formed over and between the features of the first and second sets. The spacer material is anisotropically etched to form spacers along the features of the first and second sets. The features of the first and second sets are then removed to leave a pattern of the spacers over the substrate. | 04-15-2010 |
| 20100096680 | OC DRAM CELL WITH INCREASED SENSE MARGIN - A memory device and method of making the memory device. The memory device comprises a storage transistor at a surface of a substrate. The storage transistor comprises a body portion between first and second source/drain regions, wherein the source/drain regions are regions of a first conductivity type. The storage transistor also comprises a gate structure that wraps at least partially around the body portion in at least two spatial planes. A bit line is connected to the first source/drain region and a word line is connected to the gate structure. | 04-22-2010 |
| 20100108970 | Memory Devices and Formation Methods - A method includes forming an electrical insulator material over an integrated circuit having a metal-containing conductive interconnect and activating a dopant in a semiconductor material of a substrate to provide a doped region. The doped region provides a junction of opposite conductivity types. After activating the dopant, the substrate is bonded to the insulator material and at least some of the substrate is removed where bonded to the insulator material. After the removing, a memory cell is formed having a word line, an access diode, a state-changeable memory element containing chalcogenide phase change material, and a bit line all electrically connected in series, the access diode containing the junction as a p-n junction. A memory device includes an adhesion material over the insulator material and bonding the word line to the insulator material. | 05-06-2010 |
| 20100112778 | NANOSCALE FLOATING GATE AND METHODS OF FORMATION - A memory cell is provided including a tunnel dielectric layer overlying a semiconductor substrate. The memory cell also includes a floating gate having a first portion overlying the tunnel dielectric layer and a second portion in the form of a nanorod extending from the first portion. In addition, a control gate layer is separated from the floating gate by an intergate dielectric layer. | 05-06-2010 |
| 20100112818 | METHOD FOR FORMING HIGH DENSITY PATTERNS - Methods are disclosed, such as those involving increasing the density of isolated features in an integrated circuit. In one or more embodiments, a method is provided for forming an integrated circuit with a pattern of isolated features having a final density of isolated features that is greater than a starting density of isolated features in the integrated circuit by a multiple of two or more. The method can include forming a pattern of pillars having a density X, and forming a pattern of holes amongst the pillars, the holes having a density at least X. The pillars can be selectively removed to form a pattern of holes having a density at least 2X. In some embodiments, plugs can be formed in the pattern of holes, such as by epitaxial deposition on the substrate, in order to provide a pattern of pillars having a density 2X. In other embodiments, the pattern of holes can be transferred to the substrate by etching. | 05-06-2010 |
| 20100123122 | SELECT DEVICES INCLUDING AN OPEN VOLUME, MEMORY DEVICES AND SYSTEMS INCLUDING SAME, AND METHODS FOR FORMING SAME - Select devices including an open volume that functions as a high bandgap material having a low dielectric constant are disclosed. The open volume may provide a more nonlinear, asymmetric I-V curve and enhanced rectifying behavior in the select devices. The select device may comprise, for example, a metal-insulator-insulator-metal (MIIM) device. Various methods may be used to form select devices and memory systems including such select devices. Memory devices and electronic systems include such select devices. | 05-20-2010 |
| 20100124826 | Methods Of Utilizing Block Copolymer To Form Patterns - Some embodiments include methods of utilizing block copolymer to form patterns between weirs. The methods may utilize liners along surfaces of the weirs to compensate for partial-width segments of the patterns in regions adjacent the weirs. Some embodiments include methods in which spaced apart structures are formed over a substrate, and outer surfaces of the structures are coated with a thickness of coating. Diblock copolymer is used to form a pattern across spaces between the structures. The diblock copolymer includes a pair of block constituents that have different affinities for the coating relative to one another. The pattern includes alternating segments, with the segments adjacent to the coating being shorter than the segments that are not adjacent to the coating. The coating thickness is about the amount by which the segments adjacent to the coating are shorter than the segments that are not adjacent to the coating. | 05-20-2010 |
| 20100129980 | Methods Of Forming Diodes - Some embodiments include methods of forming diodes. A stack may be formed over a first conductive material. The stack may include, in ascending order, a sacrificial material, at least one dielectric material, and a second conductive material. Spacers may be formed along opposing sidewalls of the stack, and then an entirety of the sacrificial material may be removed to leave a gap between the first conductive material and the at least one dielectric material. In some embodiments of forming diodes, a layer may be formed over a first conductive material, with the layer containing supports interspersed in sacrificial material. At least one dielectric material may be formed over the layer, and a second conductive material may be formed over the at least one dielectric material. An entirety of the sacrificial material may then be removed. | 05-27-2010 |
| 20100133612 | ELECTRONIC DEVICE WITH ASYMMETRIC GATE STRAIN - The use of strained gate electrodes in integrated circuits results in a transistor having improved carrier mobility, improved drive characteristics, and reduced source drain junction leakage. The gate electrode strain can be obtained through non symmetric placement of stress inducing structures as part of the gate electrode. | 06-03-2010 |
| 20100141265 | INTEGRATED CIRCUIT INSPECTION SYSTEM - Methods and systems that include a nanotube used as an emitter in the testing and fabrication of integrated circuits. The nanotube emits a signal to a substrate. Based on the signal or the electrical properties, e.g., current induced in the substrate by the signal, the region of the substrate is characterized. The characterization includes topology of the region of the substrate such as determining whether a recess in the substrate has a proper depth or other dimensions or characteristics of the substrate. | 06-10-2010 |
| 20100144150 | Methods of Fabricating Substrates - A method of fabricating a substrate includes forming first and second spaced features over a substrate. The first spaced features have elevationally outermost regions which are different in composition from elevationally outermost regions of the second spaced features. The first and second spaced features alternate with one another. Every other first feature is removed from the substrate and pairs of immediately adjacent second features are formed which alternate with individual of remaining of the first features. After such act of removing, the substrate is processed through a mask pattern comprising the pairs of immediately adjacent second features which alternate with individual of the remaining of the first features. Other embodiments are disclosed. | 06-10-2010 |
| 20100144151 | Methods of Fabricating Substrates - A method of fabricating a substrate includes forming spaced first features over a substrate. An alterable material is deposited over the spaced first features and the alterable material is altered with material from the spaced first features to form altered material on sidewalls of the spaced first features. A first material is deposited over the altered material, and is of some different composition from that of the altered material. The first material is etched to expose the altered material and spaced second features comprising the first material are formed on sidewalls of the altered material. Then, the altered material is etched from between the spaced second features and the spaced first features. The substrate is processed through a mask pattern comprising the spaced first features and the spaced second features. Other embodiments are disclosed. | 06-10-2010 |
| 20100144153 | Methods of Fabricating Substrates - A method of fabricating a substrate includes forming spaced first features and spaced second features over a substrate. The first and second features alternate with one another and are spaced relative one another. Width of the spaced second features is laterally trimmed to a greater degree than any lateral trimming of width of the spaced first features while laterally trimming width of the spaced second features. After laterally trimming of the second features, spacers are formed on sidewalls of the spaced first features and on sidewalls of the spaced second features. The spacers are of some different composition from that of the spaced first features and from that of the spaced second features. After forming the spacers, the spaced first features and the spaced second features are removed from the substrate. The substrate is processed through a mask pattern comprising the spacers. Other embodiments are disclosed. | 06-10-2010 |
| 20100155803 | METHOD AND STRUCTURE FOR INTEGRATING CAPACITOR-LESS MEMORY CELL WITH LOGIC - Methods for fabricating integrated circuits include fabricating a logic device on a substrate, forming an intermediate semiconductor substrate on a surface of the logic device, and fabricating a capacitor-less memory cell on the intermediate semiconductor substrate. Integrated circuits with capacitor-less memory cells formed on a surface of a logic device are also disclosed, as are multi-core microprocessors including such integrated circuits. | 06-24-2010 |
| 20100190114 | TOPOGRAPHY BASED PATTERNING - A mask having features formed by self-organizing material, such as diblock copolymers, is formed on a partially fabricated integrated circuit. Initially, a copolymer template, or seed layer, is formed on the surface of the partially fabricated integrated circuit. To form the seed layer, diblock copolymers, composed of two immiscible blocks, are deposited in the space between copolymer alignment guides. The copolymers are made to self-organize, with the guides guiding the self-organization and with each block aggregating with other blocks of the same type, thereby forming the seed layer. Next, additional, supplemental diblock copolymers are deposited over the seed layer. The copolymers in the seed layer guide self-organization of the supplemental copolymers, thereby vertically extending the pattern formed by the copolymers in the seed layer. Block species are subsequently selectively removed to form a pattern of voids defined by the remaining block species, which form a mask that can be used to pattern an underlying substrate. The supplemental copolymers augment the height of the copolymers in the seed layer, thereby facilitating the use of the copolymers for patterning the underlying substrate. | 07-29-2010 |
| 20100193897 | SEMICONDUCTOR MATERIAL MANUFACTURE - Electronic apparatus, systems, and methods include a semiconductor layer bonded to a bulk region of a wafer or a substrate, in which the semiconductor layer can be bonded to the bulk region using electromagnetic radiation. Additional apparatus, systems, and methods are disclosed. | 08-05-2010 |
| 20100207168 | Cross-Point Memory Structures, And Methods Of Forming Memory Arrays - Some embodiments include cross-point memory structures. The structures may include a line of first electrode material extending along a first horizontal direction, a multi-sided container of access device materials over the first electrode material, a memory element material within the multi-sided container, and a line of second electrode material over the memory element material and extending along a second horizontal direction that is orthogonal to the first horizontal direction. Some embodiments include methods of forming memory arrays. The methods may include forming a memory cell stack over a first electrode material, and then patterning the first electrode material and the memory cell stack into a first set of spaced lines extending along a first horizontal direction. Spaced lines of second electrode material may be formed over the first set of spaced lines, and may extend along a second horizontal direction that is orthogonal to the first horizontal direction. | 08-19-2010 |
| 20100210111 | PITCH REDUCED PATTERNS RELATIVE TOPHOTOLITHOGRAPHY FEATURES - Differently-sized features of an integrated circuit are formed by etching a substrate using a mask which is formed by combining two separately formed patterns. Pitch multiplication is used to form the relatively small features of the first pattern. Pitch multiplication is accomplished by patterning an amorphous carbon layer. Sidewall spacers are then formed on the amorphous carbon sidewalls which are then removed; the sidewall spacers defining the first mask pattern. A bottom anti-reflective coating (BARC) is then deposited to form a planar surface and a photoresist layer is formed over the BARC. The photoresist is next patterned by conventional photolithography to form the second pattern, which is transferred to the BARC. The combined pattern is transferred to an underlying amorphous silicon layer. The combined pattern is then transferred to the silicon oxide layer and then to an amorphous carbon mask layer. The combined mask pattern, is then etched into the underlying substrate. | 08-19-2010 |
| 20100213578 | METHODS OF FORMING INTEGRATED CIRCUITS AND RESULTING STRUCTURES - Methods for fabricating integrated circuit devices on an acceptor substrate devoid of circuitry are disclosed. Integrated circuit devices are formed by sequentially disposing one or more levels of semiconductor material on an acceptor substrate, and fabricating circuitry on each level of semiconductor material before disposition of a next-higher level. After encapsulation of the circuitry, the acceptor substrate is removed and semiconductor dice are singulated. Integrated circuit devices formed by the methods are also disclosed. | 08-26-2010 |
| 20100219501 | TRENCH ISOLATION IMPLANTATION - Embodiments of the disclosure include a shallow trench isolation structure having a dielectric material with energetic species implanted to a predetermined depth of the dielectric material. Embodiments further include methods of fabricating the trench structures with the implant of energetic species to the predetermined depth. In various embodiments the implant of energetic species is used to densify the dielectric material to provide a uniform wet etch rate across the surface of the dielectric material. Embodiments also include memory devices, integrated circuits, and electronic systems that include shallow trench isolation structures having the dielectric material with the high flux of energetic species implanted to the predetermined depth of the dielectric material. | 09-02-2010 |
| 20100221922 | ELECTRON BEAM PROCESSING DEVICE AND METHOD USING CARBON NANOTUBE EMITTER - Methods and devices for selective etching in a semiconductor process are shown. Chemical species generated in a reaction chamber provide both a selective etching function and concurrently form a protective coating on other regions. An electron beam provides activation to selective chemical species. In one example, reactive species are generated from a plasma source to provide an increased reactive species density. Addition of other gasses to the system can provide functions such as controlling a chemistry in a protective layer during a processing operation. In one example an electron beam array such as a carbon nanotube array is used to selectively expose a surface during a processing operation. | 09-02-2010 |
| 20100227281 | Methods Of Forming Patterns - Some embodiments include methods of forming patterns of openings. The methods may include forming spaced features over a substrate. The features may have tops and may have sidewalls extending downwardly from the tops. A first material may be formed along the tops and sidewalls of the features. The first material may be formed by spin-casting a conformal layer of the first material across the features, or by selective deposition along the features relative to the substrate. After the first material is formed, fill material may be provided between the features while leaving regions of the first material exposed. The exposed regions of the first material may then be selectively removed relative to both the fill material and the features to create the pattern of openings. | 09-09-2010 |
| 20100232220 | ELECTRONIC DEVICES FORMED OF TWO OR MORE SUBSTRATES BONDED TOGETHER, ELECTRONIC SYSTEMS COMPRISING ELECTRONIC DEVICES AND METHODS OF MAKING ELECTRONIC DEVICES - Electronic devices comprise a first substrate and a second substrate. The first substrate comprises circuitry including a plurality of conductive traces at least substantially parallel to each other through at least a portion of the first substrate. A plurality of bond pads are positioned on a surface of the first substrate and comprise a width extending over at least two of the plurality of conductive traces. A plurality of vias extend from adjacent at least some of the conductive traces to the plurality of bond pads. The second substrate is bonded to the first substrate and comprises circuitry coupled to the plurality of bond pads on the first substrate with a plurality of conductive bumps. Memory devices and related methods of forming electronic devices and memory devices are also disclosed, as are electronic systems. | 09-16-2010 |
| 20100239983 | Methods Of Forming Patterns On Substrates - A method of forming a pattern on a substrate includes forming spaced first features over a substrate. The spaced first features have opposing lateral sidewalls. Material is formed onto the opposing lateral sidewalls of the spaced first features. That portion of such material which is received against each of the opposing lateral sidewalls is of different composition from composition of each of the opposing lateral sidewalls. At least one of such portion of the material and the spaced first features is densified to move the at least one laterally away from the other of the at least one to form a void space between each of the opposing lateral sidewalls and such portion of the material. | 09-23-2010 |
| 20100248094 | Methods Of Forming And Using Reticles - Some embodiments include methods of treating reticles to provide backside masking across regions of the reticle to compensate for problems occurring during photolithographic processing. The problems may be, for example, defects in the reticle, problems associated with deposition or development of photoresist, or problems associated with substrate topography. The masking may alter one or both of transmission of electromagnetic radiation through the masked regions, and polarization of electromagnetic radiation passed through the masked regions. Some embodiments include reticles having patterns along front sides for patterning electric magnetic radiation, and masks across portions of the backsides to at least partially block transmission of electromagnetic radiation through portions of the patterns. | 09-30-2010 |
| 20100253929 | PHOTOLITHOGRAPHY SYSTEMS AND ASSOCIATED METHODS OF SELECTIVE DIE EXPOSURE - Several embodiments of photolithography systems and associated methods of selective die exposure are disclosed herein. In one embodiment, a method for exposing a microelectronic substrate in a photolithography system includes producing an illumination radiation from a radiation source and identifying a field on the microelectronic substrate to be exposed. The field is partitioned into a first region discrete from a second region. The method further includes inhibiting the illumination radiation to expose the first region while simultaneously exposing the second region to the illumination radiation. | 10-07-2010 |
| 20100258857 | Method of Forming a Layer Comprising Epitaxial Silicon, and a Field Effect Transistor - This invention includes methods of forming layers comprising epitaxial silicon, and field effect transistors. In one implementation, a method of forming a layer comprising epitaxial silicon comprises epitaxially growing a silicon-comprising layer from an exposed monocrystalline material. The epitaxially grown silicon comprises at least one of carbon, germanium, and oxygen present at a total concentration of no greater than 1 atomic percent. In one implementation, the layer comprises a silicon germanium alloy comprising at least 1 atomic percent germanium, and further comprises at least one of carbon and oxygen at a total concentration of no greater than 1 atomic percent. Other aspects and implementations are contemplated. | 10-14-2010 |
| 20100258966 | MASKING TECHNIQUES AND CONTACT IMPRINT RETICLES FOR DENSE SEMICONDUCTOR FABRICATION - A reticle comprising isolated pillars is configured for use in imprint lithography. In some embodiments, on a first substrate a pattern of pillars pitch-multiplied in two dimensions is formed in an imprint reticle. The imprint reticle is brought in contact with a transfer layer overlying a series of mask layers, which in turn overlie a second substrate. The pattern in the reticle is transferred to the transfer layer, forming an imprinted pattern. The imprinted pattern is transferred to the second substrate to form densely-spaced holes in the substrate. In other embodiments, a reticle is patterned by e-beam lithography and spacer formations. The resultant pattern of closely-spaced pillars is used to form containers in an active integrated circuit substrate. | 10-14-2010 |
| 20100267240 | PITCH MULTIPLICATION SPACERS AND METHODS OF FORMING THE SAME - Spacers in a pitch multiplication process are formed without performing a spacer etch. Rather, the mandrels are formed over a substrate and then the sides of the mandrels are reacted, e.g., in an oxidization, nitridation, or silicidation step, to form a material that can be selectively removed relative to the unreacted portions of the mandrel. The unreacted portions are selectively removed to leave a pattern of free-standing spacers. The free-standing spacers can serve as a mask for subsequent processing steps, such as etching the substrate. | 10-21-2010 |
| 20100267246 | Silicon Dioxide Deposition Methods Using at Least Ozone and TEOS as Deposition Precursors - Embodiments disclosed herein pertain to silicon dioxide deposition methods using at least ozone and tetraethylorthosilicate (TEOS) as deposition precursors. In one embodiment, a silicon dioxide deposition method using at least ozone and TEOS as deposition precursors includes flowing precursors comprising ozone and TEOS to a substrate under subatmospheric pressure conditions effective to deposit silicon dioxide-comprising material having an outer surface onto the substrate. The outer surface is treated effective to one of add hydroxyl to or remove hydroxyl from the outer surface in comparison to any hydroxyl presence on the outer surface prior to said treating. After the treating, precursors comprising ozone and TEOS are flowed to the substrate under subatmospheric pressure conditions effective to deposit silicon dioxide-comprising material onto the treated outer surface of the substrate. Other embodiments are contemplated. | 10-21-2010 |
| 20100276656 | Devices Comprising Carbon Nanotubes, And Methods Of Forming Devices Comprising Carbon Nanotubes - Some embodiments include devices that contain bundles of CNTs. An undulating topography extends over the CNTs and within spaces between the CNTs. A global maximum lateral width is defined as the greatest lateral width of any of the spaces. A material is directly over the CNTs, with the material being a plurality of particles that have minimum cross-sectional equatorial widths exceeding the global maximum lateral width. Some embodiments include methods in which a plurality of crossed carbon nanotubes are formed over a semiconductor substrate. The CNTs form an undulating upper topography extending across the CNTs and within spaces between the CNTs. A global maximum lateral width is defined as the greatest lateral width of any of the spaces. A material is deposited over the CNTs, with the material being deposited as particles that have minimum cross-sectional equatorial widths exceeding the global maximum lateral width. | 11-04-2010 |
| 20100285167 | TEMPLATES FOR USE IN IMPRINT LITHOGRAPHY AND RELATED INTERMEDIATE TEMPLATE STRUCTURES - A method of forming a template for use in imprint lithography. The method comprises providing an ultraviolet (“UV”) wavelength radiation transparent layer and forming a pattern in the UV transparent layer by photolithography. The pattern may be formed by anisotropically etching the UV transparent layer and may have feature dimensions of less than approximately 100 nm, such as dimensions of less than approximately 45 nm. An additional embodiment of the method comprises providing a UV opaque layer comprising a first pattern therein, forming a first UV transparent layer in contact with the first contact pattern of the UV opaque layer, forming a second UV transparent layer in contact with the first UV transparent layer, and removing the UV opaque layer to form the template. An intermediate template structure for use in imprint lithography is also disclosed. In other embodiments, a template that is opaque to UV wavelength radiation and a method of forming the same are disclosed. | 11-11-2010 |
| 20100285238 | METHODS OF FORMING GLASS ON A SUBSTRATE - Disclosed is a deposition process for forming a glass film. An embodiment comprising the steps of disposing a substrate in a chemical vapor deposition chamber and exposing the substrate surface to a SiO | 11-11-2010 |
| 20100295114 | Semiconductor Constructions - Some embodiments include formation of polymer spacers along sacrificial material, removal of the sacrificial material, and utilization of the polymer spacers as masks during fabrication of integrated circuitry. The polymer spacer masks may, for example, be utilized to pattern flash gates of a flash memory array. In some embodiments, the polymer is simultaneously formed across large sacrificial structures and small sacrificial structures. The polymer is thicker across the large sacrificial structures than across the small sacrificial structures, and such difference in thickness is utilized to fabricate high density structures and low-density structures with a single photomask. | 11-25-2010 |
| 20100295148 | METHODS OF UNIFORMLY REMOVING SILICON OXIDE AND AN INTERMEDIATE SEMICONDUCTOR DEVICE - A method of substantially uniformly removing silicon oxide is disclosed. The silicon oxide to be removed includes at least one cavity therein or more than one density or strain therein. The silicon oxide having at least one cavity or more than one density or strain is exposed to a gaseous mixture of NH | 11-25-2010 |
| 20100302740 | Methods of cooling semiconductor dies - The invention includes semiconductor packages having grooves within a semiconductor die backside; and includes semiconductor packages utilizing carbon nanostructures (such as, for example, carbon nanotubes) as thermally conductive interface materials. The invention also includes methods of cooling a semiconductor die in which coolant is forced through grooves in a backside of the die, and includes methods of making semiconductor packages. | 12-02-2010 |
| 20100314354 | PROFILING SOLID STATE SAMPLES - Methods and apparatus may operate to position a sample within a processing chamber and operate on a surface of the sample. Further activities may include creating a layer of reactive material in proximity with the surface, and exciting a portion of the layer of reactive material in proximity with the surface to form chemical radicals. Additional activities may include removing a portion of the material in proximity to the excited portion of the surface to a predetermined level, and continuing the creating, exciting and removing actions until at least one of a plurality of stop criteria occurs. | 12-16-2010 |
| 20100316849 | Method to Produce Nanometer-Sized Features with Directed Assembly of Block Copolymers - Methods for fabricating stamps and systems for patterning a substrate, and devices resulting from those methods are provided. | 12-16-2010 |
| 20100330770 | Diodes, And Methods Of Forming Diodes - Some embodiments include methods of forming diodes. The methods may include oxidation of an upper surface of a conductive electrode to form an oxide layer over the conductive electrode. In some embodiments, the methods may include formation of an oxidizable material over a conductive electrode, and subsequent oxidation of the oxidizable material to form an oxide layer over the conductive electrode. In some embodiments, the methods may include formation of a metal halide layer over a conductive electrode. Some embodiments include diodes that contain a metal halide layer between a pair of diode electrodes. | 12-30-2010 |
| 20110008970 | Methods of Forming Semiconductor Constructions - The invention includes methods of forming isolation regions for semiconductor constructions. A hard mask can be formed and patterned over a semiconductor substrate, with the patterned hard mask exposing a region of the substrate. Such exposed region can be etched to form a first opening having a first width. The first opening is narrowed with a conformal layer of carbon-containing material. The conformal layer is punched through to expose substrate along a bottom of the narrowed opening. The exposed substrate is removed to form a second opening which joins to the first opening, and which has a second width less than the first width. The carbon-containing material is then removed from within the first opening, and electrically insulative material is formed within the first and second openings The electrically insulative material can substantially fill the first opening, and leave a void within the second opening. | 01-13-2011 |
| 20110017401 | Electron induced chemical etching and deposition for local circuit repair - Systems and methods of imaging and repairing defects on and below the surface of an integrated circuit (IC) are described. The method may be used in areas as small as one micron in diameter, and may remove the topmost material in the small spot, repeating with various layers, until a desired depth is obtained. An energetic beam, such as an electron beam, is directed at a selected surface location. The surface has an added layer of a solid, fluid or gaseous reactive material, such as a directed stream of a fluorocarbon, and the energetic beam disassociates the reactive material in the region of the beam into radicals that chemically attack the surface. After the defect location is exposed, the method uses the energetic beam to etch undesired materials, and deposit various appropriate materials to fill gaps, and restore the IC to an operational condition. | 01-27-2011 |
| 20110024762 | Method of Forming a Thin Film Transistor - A method of forming a thin film transistor relative to a substrate includes, a) providing a thin film transistor layer of polycrystalline material on a substrate, the polycrystalline material comprising grain boundaries; b) providing a fluorine containing layer adjacent the polycrystalline thin film layer; c) annealing the fluorine containing layer at a temperature and for a time period which in combination are effective to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries; and d) providing a transistor gate operatively adjacent the thin film transistor layer. The thin film transistor can be fabricated to be bottom gated or top gated. A buffering layer can be provided intermediate the thin film transistor layer and the fluorine containing layer, with the buffering layer being transmissive of fluorine from the fluorine containing layer during the annealing. Preferably, the annealing temperature is both sufficiently high to drive fluorine from the fluorine containing layer into the polycrystalline thin film layer and incorporate fluorine within the grain boundaries to passivate said grain boundaries, but sufficiently low to prevent chemical reaction of the fluorine containing layer with the polycrystalline thin film layer. | 02-03-2011 |
| 20110045202 | Formation of Carbon-Containing Material - A method includes forming ionic clusters of carbon-containing molecules, which molecules have carbon-carbon sp | 02-24-2011 |
| 20110049606 | CHARGE-TRAP BASED MEMORY - Methods of fabricating 3D charge-trap memory cells are described, along with apparatus and systems that include them. In a planar stack formed by alternate layers of electrically conductive and insulating material, a substantially vertical opening may be formed. Inside the vertical opening a substantially vertical structure may be formed that comprises a first layer, a charge-trap layer, a tunneling oxide layer, and an epitaxial silicon portion. Additional embodiments are also described. | 03-03-2011 |
| 20110056625 | ELECTRON BEAM ETCHING DEVICE AND METHOD - Methods and devices for selective etching in a semiconductor process are shown. Chemical species generated in a reaction chamber provide both a selective etching function and concurrently form a protective coating on other regions. An electron beam provides activation to selective chemical species. In one example, reactive species are generated from a halogen and carbon containing gas source. Addition of other gasses to the system can provide functions such as controlling a chemistry in a protective layer during a processing operation. | 03-10-2011 |
| 20110062406 | Memory Devices and Formation Methods - A method includes forming an electrical insulator material over an integrated circuit having a metal-containing conductive interconnect and activating a dopant in a semiconductor material of a substrate to provide a doped region. The doped region provides a junction of opposite conductivity types. After activating the dopant, the substrate is bonded to the insulator material and at least some of the substrate is removed where bonded to the insulator material. After the removing, a memory cell is formed having a word line, an access diode, a state-changeable memory element containing chalcogenide phase change material, and a bit line all electrically connected in series, the access diode containing the junction as a p-n junction. A memory device includes an adhesion material over the insulator material and bonding the word line to the insulator material. | 03-17-2011 |
| 20110065050 | METHODS OF FORMING INTERMEDIATE SEMICONDUCTOR DEVICE STRUCTURES USING SPIN ON, PHOTOPATTERNABLE, INTERLAYER DIELECTRIC MATERIALS - A cap material may be formed over a photopatternable material on a semiconductor substrate. The cap material absorbs or reflects radiation and protects the photopatternable material from a first wavelength of radiation used in patterning the photoresist layer. Upon exposure to a first wavelength of radiation, the photopatternable material may be converted into a silicon dioxide-based material. The silicon dioxide-based material may be selectively removed. | 03-17-2011 |
| 20110068325 | Diodes, and Methods of Forming Diodes - Some embodiments include methods of forming diodes in which a first electrode is formed to have a pedestal extending upwardly from a base. At least one layer is deposited along an undulating topography that extends across the pedestal and base, and a second electrode is formed over the least one layer. The first electrode, at least one layer, and second electrode together form a structure that conducts current between the first and second electrodes when voltage of one polarity is applied to the structure, and that inhibits current flow between the first and second electrodes when voltage having a polarity opposite to said one polarity is applied to the structure. Some embodiments include diodes having a first electrode that contains two or more projections extending upwardly from a base, having at least one layer over the first electrode, and having a second electrode over the at least one layer. | 03-24-2011 |
| 20110069529 | Methods Of Reading And Using Memory Cells - Some embodiments include methods of reading memory cells. The memory cells have a write operation that occurs only if a voltage of sufficient absolute value is applied for a sufficient duration of time; and the reading is conducted with a pulse that is of too short of a time duration to be sufficient for the write operation. In some embodiments, the pulse utilized for the reading may have an absolute value of voltage that is greater than or equal to the voltage utilized for the write operation. In some embodiments, the memory cells may comprise non-ohmic devices; such as memristors and diodes. | 03-24-2011 |
| 20110073929 | HIGH COUPLING MEMORY CELL - A first dielectric layer is formed over a substrate. A single layer first conductive layer that acts as a floating gate is formed over the first dielectric layer. A trough is formed in the first conductive layer to increase the capacitive coupling of the floating gate with a control gate. An intergate dielectric layer is formed over the floating gate layer. A second conductive layer is formed over the second dielectric layer to act as a control gate. | 03-31-2011 |
| 20110117743 | MULTIPLE DEPOSITION FOR INTEGRATION OF SPACERS IN PITCH MULTIPLICATION PROCESS - Pitch multiplication is performed using a two step process to deposit spacer material on mandrels. The precursors of the first step react minimally with the mandrels, forming a barrier layer against chemical reactions for the deposition process of the second step, which uses precursors more reactive with the mandrels. Where the mandrels are formed of amorphous carbon and the spacer material is silicon oxide, the silicon oxide is first deposited by a plasma enhanced deposition process and then by a thermal chemical vapor deposition process. Oxygen gas and plasma-enhanced tetraethylorthosilicate (TEOS) are used as reactants in the plasma enhanced process, while ozone and TEOS are used as reactants in the thermal chemical vapor deposition process. The oxygen gas is less reactive with the amorphous carbon than ozone, thereby minimizing deformation of the mandrels caused by oxidation of the amorphous carbon. | 05-19-2011 |
| 20110139368 | APPARATUS AND SYSTEMS FOR INTEGRATED CIRCUIT DIAGNOSIS - Apparatus and systems provide a mechanism to examine physical properties and/or diagnose problems at a selected location of an integrated circuit. Such apparatus and systems can include a source of an energetic beam directed at the selected location. The apparatus and systems may be used to provide examination and/or diagnostic methods that may be used in areas smaller than one micron in diameter and that may be used to remove IC layers, either selectively or non-selectively, until a desired depth is obtained. | 06-16-2011 |
| 20110140195 | CROSS-POINT DIODE ARRAYS AND METHODS OF MANUFACTURING CROSS-POINT DIODE ARRAYS - Methods of forming an array of memory cells and memory cells that have pillars. Individual pillars can have a semiconductor post formed of a bulk semiconductor material and a sacrificial cap on the semiconductor post. Source regions can be between columns of the pillars, and gate lines extend along a column of pillars and are spaced apart from corresponding source regions. Each gate line surrounds a portion of the semiconductor posts along a column of pillars. The sacrificial cap structure can be selectively removed to thereby form self-aligned openings that expose a top portion of corresponding semiconductor posts. Individual drain contacts formed in the self-aligned openings are electrically connected to corresponding semiconductor posts. | 06-16-2011 |
