Patent application number | Description | Published |
20120012855 | SOLID-STATE LIGHT EMITTERS HAVING SUBSTRATES WITH THERMAL AND ELECTRICAL CONDUCTIVITY ENHANCEMENTS AND METHOD OF MANUFACTURE - Solid-state lighting devices (SSLDs) including a carrier substrate with conductors and methods of manufacturing SSLDs. The conductors can provide (a) improved thermal conductivity between a solid-state light emitter (SSLE) and a package substrate and (b) improved electrical conductivity for the SSLE. In one embodiment, the conductors have higher thermal and electrical conductivities than the carrier substrate supporting the SSLE. | 01-19-2012 |
20120032182 | SOLID STATE LIGHTS WITH THERMAL CONTROL ELEMENTS - A solid state light (“SSL”), a solid state emitter (“SSE”), and methods of manufacturing SSLs and SSEs. In one embodiment, an SSL comprises a packaging substrate having an electrical contact and a light emitting structure having a front side and a back side. The back side of the light emitting structure is superimposed with the electrical contact of the packaging substrate. The SSL can further include a temperature control element aligned with the light emitting structure and the electrical contact of the packaging substrate. | 02-09-2012 |
20120037926 | SOLID STATE LIGHTS WITH COOLING STRUCTURES - A solid state lighting (SSL) with a solid state emitter (SSE) having thermally conductive projections extending into an air channel, and methods of making and using such SSLs. The thermally conductive projections can be fins, posts, or other structures configured to transfer heat into a fluid medium, such as air. The projections can be electrical contacts between the SSE and a power source. The air channel can be oriented generally vertically such that air in the channel warmed by the SSE flows upward through the channel. | 02-16-2012 |
20120046415 | METHODS OF FORMING BLOCK COPOLYMERS, METHODS OF FORMING A SELF-ASSEMBLED BLOCK COPOLYMER STRUCTURE AND RELATED COMPOSITIONS - Methods of modifying block copolymers to enhance thermodynamic properties thereof without sacrificing material properties and methods of forming modified block copolymers having desired properties are disclosed. The modified block copolymers may be used, for example, as a mask for sublithographic patterning during various stages of semiconductor device fabrication. For example, block copolymers having desirable material properties, such as etch selectively, may be chemically modified to tailor a χ value thereof to optimize the process conditions for achieving a self-assembled state and to reduce a defectivity of the self-assembled block copolymer pattern. | 02-23-2012 |
20120108028 | Methods of Forming Electrical Components and Memory Cells - Some embodiments include methods of forming electrical components. First and second exposed surface configurations are formed over a first structure, and material is then formed across the surface configurations. The material is sub-divided amongst two or more domains, with a first of the domains being induced by the first surface configuration, and with a second of the domains being induced by the second surface configuration. A second structure is then formed over the material. The first domains of the material are incorporated into electrical components. The second domains may be replaced with dielectric material to provide isolation between adjacent electrical components, or may be utilized as intervening regions between adjacent electrical components. | 05-03-2012 |
20120164798 | METHODS OF FORMING A NONVOLATILE MEMORY CELL AND METHODS OF FORMING AN ARRAY OF NONVOLATILE MEMORY CELLS - A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material. | 06-28-2012 |
20120235106 | METHODS OF FORMING AT LEAST ONE CONDUCTIVE ELEMENT, METHODS OF FORMING A SEMICONDUCTOR STRUCTURE, METHODS OF FORMING A MEMORY CELL AND RELATED SEMICONDUCTOR STRUCTURES - Methods of forming conductive elements, such as interconnects and electrodes, for semiconductor structures and memory cells. The methods include forming a first conductive material and a second conductive material comprising silver in a portion of at least one opening and performing a polishing process to fill the at least one opening with at least one of the first and second conductive materials. An annealing process may be performed to form a mixture or an alloy of the silver and the material. The methods enable formation of silver containing conductive elements having reduced dimensions (e.g., less than about 20 nm). The resulting conductive elements have a desirable resistivity. The methods may be used, for example, to form interconnects for electrically connecting active devices and to form electrodes for memory cells. A semiconductor structure and a memory cell including such a conductive structure are also disclosed. | 09-20-2012 |
20120261638 | VERTICAL MEMORY CELL FOR HIGH-DENSITY MEMORY - This disclosure provides embodiments for the formation of vertical memory cell structures that may be implemented in RRAM devices. In one embodiment, memory cell area may be increased by varying word line height and/or word line interface surface characteristics to ensure the creation of a grain boundary that is suitable for formation of conductive pathways through an active layer of an RRAM memory cell. This may maintain continuum behavior while reducing random cell-to-cell variability that is often encountered at nanoscopic scales. In another embodiment, such vertical memory cell structures may be formed in multiple-tiers to define a three-dimensional RRAM memory array. Further embodiments also provide a spacer pitch-doubled RRAM memory array that integrates vertical memory cell structures. | 10-18-2012 |
20120264272 | Methods Of Forming A Nonvolatile Memory Cell And Methods Of Forming An Array Of Nonvolatile Memory Cells Array Of Nonvolatile Memory Cells - A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material. | 10-18-2012 |
20120267600 | MEMORY CELL REPAIR - A repairable memory cell in accordance with one or more embodiments of the present disclosure includes a storage element positioned between a first and a second electrode, and a repair element positioned between the storage element and at least one of the first electrode and the second electrode. | 10-25-2012 |
20120276725 | METHODS OF SELECTIVELY FORMING METAL-DOPED CHALCOGENIDE MATERIALS, METHODS OF SELECTIVELY DOPING CHALCOGENIDE MATERIALS, AND METHODS OF FORMING SEMICONDUCTOR DEVICE STRUCTURES INCLUDING SAME - Methods of selectively forming a metal-doped chalcogenide material comprise exposing a chalcogenide material to a transition metal solution, and incorporating transition metal of the transition solution into the chalcogenide material without substantially incorporating the transition metal into an adjacent material. The chalcogenide material is not silver selenide. Another method comprises forming a chalcogenide material adjacent to and in contact with an insulative material, exposing the chalcogenide material and the insulative material to a transition metal solution, and diffusing transition metal of the transition metal solution into the chalcogenide material while substantially no transition metal diffuses into the insulative material. A method of doping a chalcogenide material of a memory cell with at least one transition metal without using an etch or chemical mechanical planarization process to remove the transition metal from an insulative material of the memory cell is also disclosed, wherein the chalcogenide material is not silver selenide. | 11-01-2012 |
20120286640 | SOLID STATE LIGHTS WITH THERMOSIPHON LIQUID COOLING STRUCTURES AND METHODS - A solid state lighting (SSL) device with a solid state emitter (SSE) being partially exposed in a channel loop, and methods of making and using such SSLs. The SSE can have thermally conductive projections such as fins, posts, or other structures configured to transfer heat into a fluid medium, such as a liquid coolant in the channel loop. The channel loop can include an upward channel in which the SSE is exposed to warm the coolant in the upward channel, and a downward channel through which coolant moves after being cooled by a cooling structure. The coolant in the channel loop can naturally circulate due to the heat from the SSE. | 11-15-2012 |
20130001501 | MEMORY CELL STRUCTURES - The present disclosure includes memory cell structures and method of forming the same. One such memory cell includes a first electrode having sidewalls angled less than 90 degrees in relation to a bottom surface of the first electrode, a second electrode, including an electrode contact portion of the second electrode, having sidewalls angled less than 90 degrees in relation to the bottom surface of the first electrode, wherein the second electrode is over the first electrode, and a storage element between the first electrode and the electrode contact portion of the second electrode. | 01-03-2013 |
20130017335 | METHODS OF FORMING BLOCK COPOLYMERS, AND BLOCK COPOLYMER COMPOSITIONS - Methods of modifying block copolymers to enhance thermodynamic properties thereof without sacrificing material properties and methods of forming modified block copolymers having desired properties are disclosed. The modified block copolymers may be used, for example, as a mask for sublithographic patterning during various stages of semiconductor device fabrication. For example, block copolymers having desirable material properties, such as etch selectively, may be chemically modified to tailor a χ value thereof to optimize the process conditions for achieving a self-assembled state and to reduce a defectivity of the self-assembled block copolymer pattern. | 01-17-2013 |
20130037772 | Memory Cells - Some embodiments include memory cells. A memory cell may contain a switching region and an ion source region between a pair of electrodes. The switching region may be configured to reversibly retain a conductive bridge, with the memory cell being in a low resistive state when the conductive bridge is retained within the switching region and being in a high resistive state when the conductive bridge is not within the switching region. The memory cell may contain an ordered framework extending across the switching region to orient the conductive bridge within the switching region, with the framework remaining within the switching region in both the high resistive and low resistive states of the memory cell. | 02-14-2013 |
20130048940 | SOLID STATE RADIATION TRANSDUCERS AND METHODS OF MANUFACTURING - Solid state radiation transducer (SSRT) assemblies and method for making SSRT assemblies. In one embodiment, a SSRT assembly comprises a first substrate having an epitaxial growth material and a radiation transducer on the first substrate. The radiation transducer can have a first semiconductor material grown on the first substrate, a second semiconductor material, and an active region between the first and second semiconductor materials. The SSRT can also have a first contact electrically coupled to the first semiconductor material and a second contact electrically coupled to the second semiconductor material. The first substrate has an opening through which radiation can pass to and/or from the first semiconductor material. | 02-28-2013 |
20130092894 | MEMORY CELLS AND MEMORY CELL ARRAYS - Some embodiments include memory cells. The memory cells may have a first electrode, and a trench-shaped programmable material structure over the first electrode. The trench-shape defines an opening. The programmable material may be configured to reversibly retain a conductive bridge. The memory cell may have an ion source material directly against the programmable material, and may have a second electrode within the opening defined by the trench-shaped programmable material. Some embodiments include arrays of memory cells. The arrays may have first electrically conductive lines, and trench-shaped programmable material structures over the first lines. The trench-shaped structures may define openings within them. Ion source material may be directly against the programmable material, and second electrically conductive lines may be over the ion source material and within the openings defined by the trench-shaped structures. | 04-18-2013 |
20130105755 | METHODS OF FORMING SEMICONDUCTOR DEVICE STRUCTURES, AND RELATED STRUCTURES | 05-02-2013 |
20130126816 | Memory Arrays and Methods of Forming Memory Cells - Some embodiments include methods of forming memory cells. A series of rails is formed to include bottom electrode contact material. Sacrificial material is patterned into a series of lines that cross the series of rails. A pattern of the series of lines is transferred into the bottom electrode contact material. At least a portion of the sacrificial material is subsequently replaced with top electrode material. Some embodiments include memory arrays that contain a second series of electrically conductive lines crossing a first series of electrically conductive lines. Memory cells are at locations where the electrically conductive lines of the second series overlap the electrically conductive lines of the first series. First and second memory cell materials are within the memory cell locations. The first memory cell material is configured as planar sheets and the second memory cell material is configured as upwardly-opening containers. | 05-23-2013 |
20130128649 | MEMORY CELLS, SEMICONDUCTOR DEVICES INCLUDING SUCH CELLS, AND METHODS OF FABRICATION - Memory cells are disclosed, which cells include a cell material and an ion-source material over the cell material. A discontinuous interfacial material is included between the cell material and the ion-source material. Also disclosed are fabrication methods and semiconductor devices including the disclosed memory cells. | 05-23-2013 |
20130130466 | Methods of Forming Electrical Components and Memory Cells - Some embodiments include methods of forming electrical components. First and second exposed surface configurations are formed over a first structure, and material is then formed across the surface configurations. The material is sub-divided amongst two or more domains, with a first of the domains being induced by the first surface configuration, and with a second of the domains being induced by the second surface configuration. A second structure is then formed over the material. The first domains of the material are incorporated into electrical components. The second domains may be replaced with dielectric material to provide isolation between adjacent electrical components, or may be utilized as intervening regions between adjacent electrical components. | 05-23-2013 |
20130175494 | MEMORY CELLS INCLUDING TOP ELECTRODES COMPRISING METAL SILICIDE, APPARATUSES INCLUDING SUCH CELLS, AND RELATED METHODS - Memory cells (e.g., CBRAM cells) include an ion source material over an active material and an electrode comprising metal silicide over the ion source material. The ion source material may include at least one of a chalcogenide material and a metal. Apparatuses, such as systems and devices, include a plurality of such memory cells. Memory cells include an adhesion material of metal silicide between a ion source material and an electrode of elemental metal. Methods of forming a memory cell include forming a first electrode, forming an active material, forming an ion source material, and forming a second electrode including metal silicide over the metal ion source material. Methods of adhering a material including copper and a material including tungsten include forming a tungsten silicide material over a material including copper and treating the materials. | 07-11-2013 |
20130214230 | MEMORY STRUCTURES, MEMORY ARRAYS, METHODS OF FORMING MEMORY STRUCTURES AND METHODS OF FORMING MEMORY ARRAYS - Some embodiments include methods of forming memory structures. An electrically insulative line is formed over a base. Electrode material is deposited over the line and patterned to form a pair of bottom electrodes along the sidewalls of the line. Programmable material is formed over the bottom electrodes, and a top electrode is formed over the programmable material. The bottom electrodes may each contain at least one segment which extends at angle of from greater than 0° to less than or equal to about 90° relative to a planar topography of the base. Some embodiments include memory structures having a bottom electrode extending upwardly from a conductive contact to a programmable material, with the bottom electrode having a thickness of less than or equal to about 10 nanometers. Some embodiments include memory arrays and methods of forming memory arrays. | 08-22-2013 |
20130221318 | Memory Cells and Memory Cell Arrays - Some embodiments include memory cells. The memory cells may have a first electrode, and a trench-shaped programmable material structure over the first electrode. The trench-shape defines an opening. The programmable material may be configured to reversibly retain a conductive bridge. The memory cell may have an ion source material directly against the programmable material, and may have a second electrode within the opening defined by the trench-shaped programmable material. Some embodiments include arrays of memory cells. The arrays may have first electrically conductive lines, and trench-shaped programmable material structures over the first lines. The trench-shaped structures may define openings within them. Ion source material may be directly against the programmable material, and second electrically conductive lines may be over the ion source material and within the openings defined by the trench-shaped structures. | 08-29-2013 |
20130248797 | Memory Cells - Some embodiments include methods of forming memory cells. An opening is formed over a first conductive structure to expose an upper surface of the first conductive structure. The opening has a bottom level with a bottom width. The opening has a second level over the bottom level, with the second level having a second width which is greater than the bottom width. The bottom level of the opening is filled with a first portion of a multi-portion programmable material, and the second level is lined with the first portion. The lined second level is filled with a second portion of the multi-portion programmable material. A second conductive structure is formed over the second portion. Some embodiments include memory cells. | 09-26-2013 |
20130256692 | EPITAXIAL DEVICES - Epitaxial growth methods and devices are described that include a textured surface on a substrate. Geometry of the textured surface provides a reduced lattice mismatch between an epitaxial material and the substrate. Devices formed by the methods described exhibit better interfacial adhesion and lower defect density than devices formed without texture. Silicon substrates are shown with gallium nitride epitaxial growth and devices such as LEDs are formed within the gallium nitride. | 10-03-2013 |
20130306930 | Memory Cells - Some embodiments include memory cells. A memory cell may contain a switching region and an ion source region between a pair of electrodes. The switching region may be configured to reversibly retain a conductive bridge, with the memory cell being in a low resistive state when the conductive bridge is retained within the switching region and being in a high resistive state when the conductive bridge is not within the switching region. The memory cell may contain an ordered framework extending across the switching region to orient the conductive bridge within the switching region, with the framework remaining within the switching region in both the high resistive and low resistive states of the memory cell. | 11-21-2013 |
20130320283 | Memory Arrays And Methods Of Forming An Array Of Memory Cells - A method of forming an array of memory cells includes forming lines of covering material that are elevationally over and along lines of spaced sense line contacts. Longitudinal orientation of the lines of covering material is used in forming lines comprising programmable material and outer electrode material that are between and along the lines of covering material. The covering material is removed over the spaced sense line contacts and the spaced sense line contacts are exposed. Access lines are formed. Sense lines are formed that are electrically coupled to the spaced sense line contacts. The sense lines are angled relative to the lines of spaced sense line contacts and relative to the access lines. Other embodiments, including structure independent of method, are disclosed. | 12-05-2013 |
20130320291 | SEMICONDUCTOR STRUCTURES AND MEMORY CELLS INCLUDING CONDUCTIVE MATERIAL AND METHODS OF FABRICATION - Methods of forming conductive elements, such as interconnects and electrodes, for semiconductor structures and memory cells. The methods include forming a first conductive material and a second conductive material comprising silver in a portion of at least one opening and performing a polishing process to fill the at least one opening with at least one of the first and second conductive materials. An annealing process may be performed to form a mixture or an alloy of the silver and the first conductive material. The methods enable formation of silver containing conductive elements having reduced dimensions (e.g., less than about 20 nm). The resulting conductive elements have a desirable resistivity. The methods may be used, for example, to form interconnects for electrically connecting active devices and to form electrodes for memory cells. A semiconductor structure and a memory cell including such a conductive structure are also disclosed. | 12-05-2013 |
20130341586 | Memory Structures, Memory Arrays, Methods of Forming Memory Structures and Methods of Forming Memory Arrays - Some embodiments include methods of forming memory structures. An electrically insulative line is formed over a base. Electrode material is deposited over the line and patterned to form a pair of bottom electrodes along the sidewalls of the line. Programmable material is formed over the bottom electrodes, and a top electrode is formed over the programmable material. The bottom electrodes may each contain at least one segment which extends at angle of from greater than 0° to less than or equal to about 90° relative to a planar topography of the base. Some embodiments include memory structures having a bottom electrode extending upwardly from a conductive contact to a programmable material, with the bottom electrode having a thickness of less than or equal to about 10 nanometers. Some embodiments include memory arrays and methods of forming memory arrays. | 12-26-2013 |
20140120686 | Methods Of Forming A Nonvolatile Memory Cell And Methods Of Forming An Array Of Nonvolatile Memory Cells - A method of forming a nonvolatile memory cell includes forming a first electrode and a second electrode of the memory cell. Sacrificial material is provided between the first second electrodes. The sacrificial material is exchanged with programmable material. The sacrificial material may additionally be exchanged with select device material. | 05-01-2014 |
20140138608 | MEMORY CELL STRUCTURES - The present disclosure includes memory cell structures and method of forming the same. One such memory cell includes a first electrode having sidewalls angled less than 90 degrees in relation to a bottom surface of the first electrode, a second electrode, including an electrode contact portion of the second electrode, having sidewalls angled less than 90 degrees in relation to the bottom surface of the first electrode, wherein the second electrode is over the first electrode, and a storage element between the first electrode and the electrode contact portion of the second electrode. | 05-22-2014 |
20140167214 | MEMORY CELL REPAIR - A repairable memory cell in accordance with one or more embodiments of the present disclosure includes a storage element positioned between a first and a second electrode, and a repair element positioned between the storage element and at least one of the first electrode and the second electrode. | 06-19-2014 |
20140169066 | RESISTIVE MEMORY SENSING - The present disclosure includes apparatuses and methods for sensing a resistive memory cell. A number of embodiments include performing a sensing operation on a memory cell to determine a current value associated with the memory cell, applying a programming signal to the memory cell, and determining a data state of the memory cell based on the current value associated with the memory cell before applying the programming signal and a current value associated with the memory cell after applying the programming signal. | 06-19-2014 |
20140179115 | 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. | 06-26-2014 |
20140191182 | Memory Cells - Some embodiments include a method of forming a memory cell. A first portion of a switching region is formed over a first electrode. A second portion of the switching region is formed over the first portion using atomic layer deposition. The second portion is a different composition than the first portion. An ion source region is formed over the switching region. A second electrode is formed over the ion source region. Some embodiments include a memory cell having a switching region between a pair of electrodes. The switching region is configured to be reversibly transitioned between a low resistive state and a high resistive state. The switching region includes two or more discrete portions, with one of the portions not having a non-oxygen component in common with any composition directly against it in the high resistive state. | 07-10-2014 |
20140205752 | Methods of Utilizing Block Copolymer to Form Patterns - Some embodiments include methods of forming patterns. A block copolymer film may be formed over a substrate, with the block copolymer having an intrinsic glass transition temperature (T | 07-24-2014 |
20140233293 | PERMUTATIONAL MEMORY CELLS - Various embodiments comprise apparatuses having at least two resistance change memory (RCM) cells. In one embodiment, an apparatus includes at least two electrical contacts coupled to each of the RCM cells. A memory cell material is disposed between pairs of each of the electrical contacts coupled to each of the RCM cells. The memory cell material is capable of forming a conductive pathway between the electrical contacts with at least a portion of the memory cell material arranged to cross-couple a conductive pathway between select ones of the at least two electrical contacts electrically coupled to each of the at least two RCM cells. Additional apparatuses and methods are described. | 08-21-2014 |
20140233298 | APPARATUS AND METHODS FOR FORMING A MEMORY CELL USING CHARGE MONITORING - Apparatuses and methods of forming a memory cell is described. In one such method, a forming charge applied to a memory cell, such as a Resistive RAM (RRAM) memory cell, is monitored to determine the progress of the forming the cell. If the cell is consuming charge too slowly, a higher voltage can be applied. If the cell is consuming charge too quickly, a lower voltage can be applied. The charge may be monitored by charging a capacitor to a certain level, then monitoring the discharge rate of the capacitor though the cell. The monitoring may use comparators to measure the charge. The monitoring may also use an analog to digital converter to perform the monitoring. | 08-21-2014 |
20140252303 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include methods of forming memory cells. An opening is formed over a first conductive structure to expose an upper surface of the first conductive structure. The opening has a bottom level with a bottom width. The opening has a second level over the bottom level, with the second level having a second width which is greater than the bottom width. The bottom level of the opening is filled with a first portion of a multi-portion programmable material, and the second level is lined with the first portion. The lined second level is filled with a second portion of the multi-portion programmable material. A second conductive structure is formed over the second portion. Some embodiments include memory cells. | 09-11-2014 |
20140284614 | METHODS FOR EPITAXIAL DEVICES - Epitaxial growth methods and devices are described that include a textured surface on a substrate. Geometry of the textured surface provides a reduced lattice mismatch between an epitaxial material and the substrate. Devices formed by the methods described exhibit better interfacial adhesion and lower defect density than devices formed without texture. Silicon substrates are shown with gallium nitride epitaxial growth and devices such as LEDs are formed within the gallium nitride. | 09-25-2014 |
20140319536 | SOLID STATE LIGHTING DEVICES WITH CELLULAR ARRAYS AND ASSOCIATED METHODS OF MANUFACTURING - Solid state lighting (“SSL”) devices with cellular arrays and associated methods of manufacturing are disclosed herein. In one embodiment, a light emitting diode includes a semiconductor material having a first surface and a second surface opposite the first surface. The semiconductor material has an aperture extending into the semiconductor material from the first surface. The light emitting diode also includes an active region in direct contact with the semiconductor material, and at least a portion of the active region is in the aperture of the semiconductor material. | 10-30-2014 |
20140339494 | Memory Cells and Memory Cell Arrays - Some embodiments include memory cells. The memory cells may have a first electrode, and a trench-shaped programmable material structure over the first electrode. The trench-shape defines an opening. The programmable material may be configured to reversibly retain a conductive bridge. The memory cell may have an ion source material directly against the programmable material, and may have a second electrode within the opening defined by the trench-shaped programmable material. Some embodiments include arrays of memory cells. The arrays may have first electrically conductive lines, and trench-shaped programmable material structures over the first lines. The trench-shaped structures may define openings within them. Ion source material may be directly against the programmable material, and second electrically conductive lines may be over the ion source material and within the openings defined by the trench-shaped structures. | 11-20-2014 |
20140346428 | MEMORY CELL STRUCTURES - The present disclosure includes memory cell structures and method of forming the same. One such method includes forming a memory cell includes forming, in a first direction, a select device stack including a select device formed between a first electrode and a second electrode; forming, in a second direction, a plurality of sacrificial material lines over the select device stack to form a via; forming a programmable material stack within the via; and removing the plurality of sacrificial material lines and etching through a portion of the select device stack to isolate the select device. | 11-27-2014 |
20140346431 | Memory Structures, Memory Arrays, Methods of Forming Memory Structures and Methods of Forming Memory Arrays - Some embodiments include methods of forming memory structures. An electrically insulative line is formed over a base. Electrode material is deposited over the line and patterned to form a pair of bottom electrodes along the sidewalls of the line. Programmable material is formed over the bottom electrodes, and a top electrode is formed over the programmable material. The bottom electrodes may each contain at least one segment which extends at angle of from greater than 0° to less than or equal to about 90° relative to a planar topography of the base. Some embodiments include memory structures having a bottom electrode extending upwardly from a conductive contact to a programmable material, with the bottom electrode having a thickness of less than or equal to about 10 nanometers. Some embodiments include memory arrays and methods of forming memory arrays. | 11-27-2014 |
20140347914 | MULTI-FUNCTION RESISTANCE CHANGE MEMORY CELLS AND APPARATUSES INCLUDING THE SAME - Various embodiments comprise apparatuses including drive circuitry to provide signal pulses of a selected time duration and/or amplitude to a number of memory cells. The memory cells may include an array of resistance change memory cells to be electrically coupled to the drive circuitry. The resistance change memory cells may be programmed for a range of retention time periods and operating speeds based on the received signal pulse. Additional apparatuses and methods are described. | 11-27-2014 |
20140349486 | Methods of Utilizing Block Copolymer to Form Patterns - Some embodiments include methods of forming patterns utilizing copolymer. A main body of copolymer may be formed across a substrate, and self-assembly of the copolymer may be induced to form a pattern of structures across the substrate. A uniform thickness throughout the main body of the copolymer may be maintained during the inducement of the self-assembly. In some embodiments, the uniform thickness may be maintained through utilization of a wall surrounding the main body of copolymer to impede dispersal of the copolymer from the main body. In some embodiments, the uniform thickness may be maintained through utilization of a volume of copolymer in fluid communication with the main body of copolymer. | 11-27-2014 |
20140361239 | THREE DIMENSIONAL MEMORY ARRAY WITH SELECT DEVICE - Three dimensional memory arrays and methods of forming the same are provided. An example three dimensional memory array can include a stack comprising a plurality of first conductive lines separated from one another by at least an insulation material, and at least one conductive extension arranged to extend substantially perpendicular to the plurality of first conductive lines such that the at least one conductive extension intersects each of the plurality of first conductive lines. Storage element material is arranged around the at least one conductive extension, and a select device is arranged around the storage element material. The storage element material is radially adjacent an insulation material separating the plurality of first conductive lines, and the plurality of materials arranged around the storage element material are radially adjacent each of the plurality of first conductive lines. | 12-11-2014 |
20150028347 | LIGHT EMITTING DIODES AND ASSOCIATED METHODS OF MANUFACTURING - Light emitting diodes and associated methods of manufacturing are disclosed herein. In one embodiment, a light emitting diode (LED) includes a substrate, a semiconductor material carried by the substrate, and an active region proximate to the semiconductor material. The semiconductor material has a first surface proximate to the substrate and a second surface opposite the first surface. The second surface of the semiconductor material is generally non-planar, and the active region generally conforms to the non-planar second surface of the semiconductor material. | 01-29-2015 |
20150041746 | NON-VOLATILE MEMORY SYSTEM WITH RELIABILITY ENHANCEMENT MECHANISM AND METHOD OF MANUFACTURE THEREOF - A method of manufacture of a non-volatile memory system comprising: forming a dielectric layer having a hole; depositing a first electrode in the hole of the dielectric layer; applying an ion source layer over the first electrode; and depositing a second electrode over the ion source layer including: depositing an interface layer on the ion source layer, and applying a cap layer on the interface layer. | 02-12-2015 |
20150060751 | MEMORY CELLS WITH RECESSED ELECTRODE CONTACTS - Memory cells with recessed electrode contacts and methods of forming the same are provided. An example memory cell can include an electrode contact formed in a substrate. An upper surface of the electrode contact is recessed a distance relative to an upper surface of the substrate. A first portion of a memory element is formed on an upper surface of the electrode contact and the upper surface of the substrate. | 03-05-2015 |
20150076436 | METHODS OF FORMING SEMICONDUCTOR DEVICE STRUCTURES, AND RELATED SEMICONDUCTOR DEVICE STRUCTURES - A method of forming a semiconductor device structure. The method comprises forming a block copolymer assembly comprising at least two different domains over an electrode. At least one metal precursor is selectively coupled to the block copolymer assembly to form a metal-complexed block copolymer assembly comprising at least one metal-complexed domain and at least one non-metal-complexed domain. The metal-complexed block copolymer assembly is annealed in to form at least one metal structure. Other methods of forming a semiconductor device structures are described. Semiconductor device structures are also described. | 03-19-2015 |
20150103613 | MEMORY DEVICES AND METHODS OF OPERATING THE SAME - The present disclosure includes memory devices and methods of operating the same. One such device includes an array of groups of memory cells, a group selector configured to select a particular group of memory cells from within the array, and a cell selector configured to select a particular memory cell from within the selected particular group of memory cells. | 04-16-2015 |
20150123064 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a memory cell having an electrode and a switching material over the electrode. The electrode is a first composition which includes a first metal and a second metal. The switching material is a second composition which includes the second metal. The second composition is directly against the first composition. Some embodiments include methods of forming memory cells. | 05-07-2015 |
20150123065 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a memory cell that has an electrode, a switching material over the electrode, a buffer region over the switching material, and an ion reservoir material over the buffer region. The buffer region includes one or more elements from Group 14 of the periodic table in combination with one or more chalcogen elements. Some embodiments include methods of forming memory cells. | 05-07-2015 |
20150124517 | APPARATUS AND METHODS FOR FORMING A MEMORY CELL USING CHARGE MONITORING - Apparatus and methods of forming a memory cell are described. In one such method, a forming charge applied to a memory cell, such as a Resistive RAM (RRAM) memory cell, is monitored to determine the progress of the forming the cell. If the cell is consuming charge too slowly, a higher voltage can be applied. If the cell is consuming charge too quickly, a lower voltage can be applied. The charge may be monitored by charging a capacitor to a certain level, then monitoring the discharge rate of the capacitor though the cell. The monitoring may use comparators to measure the charge. The monitoring may also use an analog to digital converter to perform the monitoring. | 05-07-2015 |
20150140776 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a method of forming a memory cell. A first portion of a switching region is formed over a first electrode. A second portion of the switching region is formed over the first portion using atomic layer deposition. The second portion is a different composition than the first portion. An ion source region is formed over the switching region. A second electrode is formed over the ion source region. Some embodiments include a memory cell having a switching region between a pair of electrodes. The switching region is configured to be reversibly transitioned between a low resistive state and a high resistive state. The switching region includes two or more discrete portions, with one of the portions not having a non-oxygen component in common with any composition directly against it in the high resistive state. | 05-21-2015 |
20150140777 | METHODS OF SELECTIVELY DOPING CHALCOGENIDE MATERIALS AND METHODS OF FORMING SEMICONDUCTOR DEVICES - Methods of selectively forming a metal-doped chalcogenide material comprise exposing a chalcogenide material to a transition metal solution, and incorporating transition metal of the transition solution into the chalcogenide material without substantially incorporating the transition metal into an adjacent material. The chalcogenide material is not silver selenide. Another method comprises forming a chalcogenide material adjacent to and in contact with an insulative material, exposing the chalcogenide material and the insulative material to a transition metal solution, and diffusing transition metal of the transition metal solution into the chalcogenide material while substantially no transition metal diffuses into the insulative material. A method of doping a chalcogenide material of a memory cell with at least one transition metal without using an etch or chemical mechanical planarization process to remove the transition metal from an insulative material of the memory cell is also disclosed, wherein the chalcogenide material is not silver selenide. | 05-21-2015 |
20150179936 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a memory cell having a first electrode, and an intermediate material over and directly against the first electrode. The intermediate material includes stabilizing species corresponding to one or both of carbon and boron. The memory cell also has a switching material over and directly against the intermediate material, an ion reservoir material over the switching material, and a second electrode over the ion reservoir material. Some embodiments include methods of forming memory cells. | 06-25-2015 |
20150194211 | PERMUTATIONAL MEMORY CELLS - Various embodiments include at least one resistance change memory (RCM) cell, In one embodiment, three or more pairs of electrical contacts are coupled to the at least one RCM cell. A first portion of the pairs are arranged laterally to one another in a first grouping and a second opposing portion of the pairs are arranged laterally to one another in a second grouping. A memory cell material is disposed between opposing sides of the pairs of the three or more electrical contacts. The memory cell material is configured to form a conductive pathway between one or more of the pairs, with each of the three or more pairs being configured to be accessed individually for at least one operation including program, erase, and read operations. Additional apparatuses and methods are described. | 07-09-2015 |
20150194212 | Memory Systems and Memory Programming Methods - Memory systems and memory programming methods are described. According to one arrangement, a memory system includes a memory array comprising a plurality of memory cells individually configured to have a plurality of different memory states, access circuitry configured to apply signals to the memory cells to program the memory cells to the different memory states, and a controller to configured to control the access circuitry to apply a first of the signals to one of the memory cells to program the one memory cell from a first memory state to a second memory state different than the first memory state, to determine that the one memory cell failed to place into the second memory state as a result of the application of the first signal, and to control the access circuitry to apply a second signal to the one memory cell to program the one memory cell from the first memory state to the second memory state as a result of the determination, wherein the first and second signals have a different electrical characteristic. | 07-09-2015 |
20150200364 | MEMORY CELL STRUCTURES - The present disclosure includes memory cell structures and method of forming the same. One such memory cell includes a first electrode having sidewalls angled less than 90 degrees in relation to a bottom surface of the first electrode, a second electrode, including an electrode contact portion of the second electrode, having sidewalls angled less than 90 degrees in relation to the bottom surface of the first electrode, wherein the second electrode is over the first electrode, and a storage element between the first electrode and the electrode contact portion of the second electrode. | 07-16-2015 |
20150214477 | MEMORY CELLS AND METHODS OF FABRICATION - Memory cells are disclosed, which cells include a cell material and an ion-source material over the cell material. A discontinuous interfacial material is included between the cell material and the ion-source material. Also disclosed are fabrication methods and semiconductor devices including the disclosed memory cells. | 07-30-2015 |
20150221864 | Memory Cells and Memory Cell Arrays - Some embodiments include memory cells. The memory cells may have a first electrode, and a trench-shaped programmable material structure over the first electrode. The trench-shape defines an opening. The programmable material may be configured to reversibly retain a conductive bridge. The memory cell may have an ion source material directly against the programmable material, and may have a second electrode within the opening defined by the trench-shaped programmable material. Some embodiments include arrays of memory cells. The arrays may have first electrically conductive lines, and trench-shaped programmable material structures over the first lines. The trench-shaped structures may define openings within them. Ion source material may be directly against the programmable material, and second electrically conductive lines may be over the ion source material and within the openings defined by the trench-shaped structures. | 08-06-2015 |
20150255153 | RESISTIVE MEMORY SENSING - The present disclosure includes apparatuses and methods for sensing a resistive memory cell. A number of embodiments include performing a sensing operation on a memory cell to determine a current value associated with the memory cell, applying a programming signal to the memory cell, and determining a data state of the memory cell based on the current value associated with the memory cell before applying the programming signal and a current value associated with the memory cell after applying the programming signal. | 09-10-2015 |
20150295171 | MEMORY CELLS AND SEMICONDUCTOR STRUCTURES INCLUDING ELECTRODES COMPRISING A METAL, AND RELATED METHODS - Memory cells (e.g., CBRAM cells) include an ion source material over an active material and an electrode comprising metal silicide over the ion source material. The ion source material may include at least one of a chalcogenide material and a metal. Apparatuses, such as systems and devices, include a plurality of such memory cells. Memory cells include an adhesion material of metal silicide between a ion source material and an electrode of elemental metal. Methods of forming a memory cell include forming a first electrode, forming an active material, forming an ion source material, and forming a second electrode including metal silicide over the metal ion source material. Methods of adhering a material including copper and a material including tungsten include forming a tungsten silicide material over a material including copper and treating the materials. | 10-15-2015 |
20150349204 | EPITAXIAL DEVICES - Epitaxial growth methods and devices are described that include a textured surface on a substrate. Geometry of the textured surface provides a reduced lattice mismatch between an epitaxial material and the substrate. Devices formed by the methods described exhibit better interfacial adhesion and lower defect density than devices formed without texture. Silicon substrates are shown with gallium nitride epitaxial growth and devices such as LEDs are formed within the gallium nitride. | 12-03-2015 |
20150364683 | MEMORY CELLS WITH RECESSED ELECTRODE CONTACTS - Memory cells with recessed electrode contacts and methods of forming the same are provided. An example memory cell can include an electrode contact formed in a substrate. An upper surface of the electrode contact is recessed a distance relative to an upper surface of the substrate. A first portion of a memory element is formed on an upper surface of the electrode contact and the upper surface of the substrate. | 12-17-2015 |
20150380645 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a memory cell having an electrode and a switching material over the electrode. The electrode is a first composition which includes a first metal and a second metal. The switching material is a second composition which includes the second metal. The second composition is directly against the first composition. Some embodiments include methods of forming memory cells. | 12-31-2015 |
20160035974 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a memory cell having a first electrode, and an intermediate material over and directly against the first electrode. The intermediate material includes stabilizing species corresponding to one or both of carbon and boron. The memory cell also has a switching material over and directly against the intermediate material, an ion reservoir material over the switching material, and a second electrode over the ion reservoir material. Some embodiments include methods of forming memory cells. | 02-04-2016 |
20160072016 | SOLID-STATE LIGHT EMITTERS HAVING SUBSTRATES WITH THERMAL AND ELECTRICAL CONDUCTIVITY ENHANCEMENTS AND METHOD OF MANUFACTURE - Solid-state lighting devices (SSLDs) including a carrier substrate with conductors and methods of manufacturing SSLDs. The conductors can provide (a) improved thermal conductivity between a solid-state light emitter (SSLE) and a package substrate and (b) improved electrical conductivity for the SSLE. In one embodiment, the conductors have higher thermal and electrical conductivities than the carrier substrate supporting the SSLE. | 03-10-2016 |
20160093803 | Memory Cells and Methods of Forming Memory Cells - Some embodiments include a memory cell that has an electrode, a switching material over the electrode, a buffer region over the switching material, and an ion reservoir material over the buffer region. The buffer region includes one or more elements from Group 14 of the periodic table in combination with one or more chalcogen elements. Some embodiments include methods of forming memory cells. | 03-31-2016 |