Patent application number | Description | Published |
20090092933 | Methods of Lithographically Patterning a Substrate - A method of lithographically patterning a substrate that has photoresist having removal areas and non-removal areas includes first exposing at least the non-removal areas to radiation effective to increase outer surface roughness of the photoresist in the non-removal areas at least post-develop but ineffective to change photoresist solubility in a developer for the photoresist to be cleared from the non-removal areas upon develop with the developer. Second exposing of radiation to the removal areas is conducted to be effective to change photoresist solubility in the developer for the photoresist to be cleared from the removal areas upon develop with the developer. The photoresist is developed with the developer effective to clear photoresist from the removal areas and to leave photoresist in the non-removal areas that has outer surface roughness in the non-removal areas which is greater than that before the first exposing. Other implementations and embodiments are contemplated. | 04-09-2009 |
20100092873 | Methods Of Utilizing Block Copolymer To Form Patterns - Some embodiments include methods of forming patterns in which a block copolymer-containing composition is formed over a substrate, and is then patterned to form a first mask. The block copolymer of the composition is subsequently induced into forming a repeating pattern within the first mask. Portions of the repeating pattern are then removed to form a second mask from the first mask. The patterning of the block copolymer-containing composition may utilize photolithography. Alternatively, the substrate may have regions which wet differently relative to one another with respect to the block copolymer-containing composition, and the patterning of the first mask may utilize such differences in wetting in forming the first mask. | 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 |
20100137496 | Block Copolymer-Comprising Compositions and Methods of Purifying PS-b-PXVP - In one embodiment, a block copolymer-containing composition includes PS-b-PXVP and a lithium salt, where “X” is 2 or 4. All lithium salt is present in the composition at no greater than 1 ppm by weight. In one embodiment, a homogenous block copolymer-including comprising has PS-b-PXVP present in the composition at no less than 99.99998% by weight, where “X” is 2 or 4. Methods of forming such compositions are disclosed. | 06-03-2010 |
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 |
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 |
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 |
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 |
20100295183 | METHOD FOR PROVIDING ELECTRICAL CONNECTIONS TO SPACED CONDUCTIVE LINES - An integrated circuit and a method of formation provide a contact area formed at an angled end of at least one linearly extending conductive line. In an embodiment, conductive lines with contact landing pads are formed by patterning lines in a mask material, cutting at least one of the material lines to form an angle relative to the extending direction of the material lines, forming extensions from the angled end faces of the mask material, and patterning an underlying conductor by etching using said material lines and extension as a mask. In another embodiment, at least one conductive line is cut at an angle relative to the extending direction of the conductive line to produce an angled end face, and an electrical contact landing pad is formed in contact with the angled end face. | 11-25-2010 |
20100323096 | Methods Of Utlizing 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. | 12-23-2010 |
20110117733 | Methods Of Utilizing Block Copolymers To Form Patterns - Some embodiments include methods of forming patterns utilizing copolymer. A copolymer composition is formed across a substrate. The composition includes subunits A and B, and will be self-assembled to form core structures spaced center-to-center by a distance of L | 05-19-2011 |
20110151668 | PITCH DIVISION PATTERNING TECHNIQUES - Embodiments of the invention comprise pitch division techniques to extend the capabilities of lithographic techniques beyond their minimum pitch. The pitch division techniques described herein employ additional processing to ensure pitch divided lines have the spatial isolation necessary to prevent shorting problems. The pitch division techniques described herein further employ processing acts to increase the structural robustness of high aspect ratio features. | 06-23-2011 |
20110193115 | 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. | 08-11-2011 |
20110233581 | 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. | 09-29-2011 |
20110250745 | METHODS OF FORMING PATTERNS, AND METHODS OF FORMING INTEGRATED CIRCUITS - Some embodiments include methods of forming patterns in substrates by utilizing block copolymer assemblies as patterning materials. A block copolymer assembly may be formed over a substrate, with the assembly having first and second subunits arranged in a pattern of two or more domains. Metal may be selectively coupled to the first subunits relative to the second subunits to form a pattern of metal-containing regions and non-metal-containing regions. At least some of the block copolymer may be removed to form a patterned mask corresponding to the metal-containing regions. A pattern defined by the patterned mask may be transferred into the substrate with one or more etches. In some embodiments, the patterning may be utilized to form integrated circuitry, such as, for example, gatelines. | 10-13-2011 |
20110272381 | 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 | 11-10-2011 |
20110297646 | Methods Of Forming Patterns On Substrates - A method of forming a pattern on a substrate includes forming spaced features over a substrate. A polymer is adsorbed to outer lateral surfaces of the spaced features. Either material of the spaced features is removed selectively relative to the adsorbed polymer or material of the adsorbed polymer is removed selectively relative to the spaced features to form a pattern on the substrate. In one embodiment, the polymer is of known chain length and has opposing longitudinal ends. One of the longitudinal ends of the polymer adsorbs to the outer lateral surfaces whereby the adsorbed polymer projects lengthwise from the outer lateral surfaces, with said chain length defining a substantially uniform lateral thickness of the adsorbed polymer on the spaced features. Additional embodiments are contemplated. | 12-08-2011 |
20110298014 | Cross-Point Memory Structures - 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. | 12-08-2011 |
20110316021 | EPITAXIAL GROWTH METHOD AND 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. | 12-29-2011 |
20120009784 | METHOD FOR PROVIDING ELECTRICAL CONNECTIONS TO SPACED CONDUCTIVE LINES - An integrated circuit and a method of formation provide a contact area formed at an angled end of at least one linearly extending conductive line. In an embodiment, conductive lines with contact landing pads are formed by patterning lines in a mask material, cutting at least one of the material lines to form an angle relative to the extending direction of the material lines, forming extensions from the angled end faces of the mask material, and patterning an underlying conductor by etching using said material lines and extension as a mask. In another embodiment, at least one conductive line is cut at an angle relative to the extending direction of the conductive line to produce an angled end face, and an electrical contact landing pad is formed in contact with the angled end face. | 01-12-2012 |
20120045891 | Methods Of Forming Patterns, And Methods Of Forming Integrated Circuits - Some embodiments include methods of forming patterns in substrates by utilizing block copolymer assemblies as patterning materials. A block copolymer assembly may be formed over a substrate, with the assembly having first and second subunits arranged in a pattern of two or more domains. Metal may be selectively coupled to the first subunits relative to the second subunits to form a pattern of metal-containing regions and non-metal-containing regions. At least some of the block copolymer may be removed to form a patterned mask corresponding to the metal-containing regions. A pattern defined by the patterned mask may be transferred into the substrate with one or more etches. In some embodiments, the patterning may be utilized to form integrated circuitry, such as, for example, gatelines. | 02-23-2012 |
20120077127 | Methods Of Forming Patterns - Some embodiments include methods of forming patterns in which a block copolymer-containing composition is formed over a substrate, and is then patterned to form a first mask. The block copolymer of the composition is subsequently induced into forming a repeating pattern within the first mask. Portions of the repeating pattern are then removed to form a second mask from the first mask. The patterning of the block copolymer-containing composition may utilize photolithography. Alternatively, the substrate may have regions which wet differently relative to one another with respect to the block copolymer-containing composition, and the patterning of the first mask may utilize such differences in wetting in forming the first mask. | 03-29-2012 |
20120141943 | 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. | 06-07-2012 |
20120181705 | PITCH DIVISION PATTERNING TECHNIQUES - Embodiments of the invention comprise pitch division techniques to extend the capabilities of lithographic techniques beyond their minimum pitch. The pitch division techniques described herein employ additional processing to ensure pitch divided lines have the spatial isolation necessary to prevent shorting problems. The pitch division techniques described herein further employ processing acts to increase the structural robustness of high aspect ratio features. | 07-19-2012 |
20120235211 | Cross-Point Memory Structures - 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. | 09-20-2012 |
20120237880 | 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. | 09-20-2012 |
20120256191 | EPITAXIAL GROWTH METHOD AND 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. | 10-11-2012 |
20120295445 | 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. | 11-22-2012 |
20120315769 | Methods of Utilizing Block Copolymers to Form Patterns - Some embodiments include methods of forming patterns utilizing copolymer. A copolymer composition is formed across a substrate. The composition includes subunits A and B, and will be self-assembled to form core structures spaced center-to-center by a distance of L | 12-13-2012 |
20120322269 | 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. | 12-20-2012 |
20130005065 | 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. | 01-03-2013 |
20130005903 | Block Copolymer-Comprising Compositions and Methods of Purifying PS-b-PXVP - In one embodiment, a block copolymer-containing composition includes PS-b-PXVP and a lithium salt, where “X” is 2 or 4. All lithium salt is present in the composition at no greater than 1 ppm by weight. In one embodiment, a homogenous block copolymer-including comprising has PS-b-PXVP present in the composition at no less than 99.99998% by weight, where “X” is 2 or 4. Methods of forming such compositions are disclosed. | 01-03-2013 |
20130059255 | Methods of Lithographically Patterning a Substrate - A method of lithographically patterning a substrate that has photoresist having removal areas and non-removal areas includes first exposing at least the non-removal areas to radiation effective to increase outer surface roughness of the photoresist in the non-removal areas at least post-develop but ineffective to change photoresist solubility in a developer for the photoresist to be cleared from the non-removal areas upon develop with the developer. Second exposing of radiation to the removal areas is conducted to be effective to change photoresist solubility in the developer for the photoresist to be cleared from the removal areas upon develop with the developer. The photoresist is developed with the developer effective to clear photoresist from the removal areas and to leave photoresist in the non-removal areas that has outer surface roughness in the non-removal areas which is greater than that before the first exposing. Other implementations and embodiments are contemplated. | 03-07-2013 |
20130102160 | 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. | 04-25-2013 |
20130210230 | METHOD FOR PROVIDING ELECTRICAL CONNECTIONS TO SPACED CONDUCTIVE LINES - An integrated circuit and a method of formation provide a contact area formed at an angled end of at least one linearly extending conductive line. In an embodiment, conductive lines with contact landing pads are formed by patterning lines in a mask material, cutting at least one of the material lines to form an angle relative to the extending direction of the material lines, forming extensions from the angled end faces of the mask material, and patterning an underlying conductor by etching using said material lines and extension as a mask. In another embodiment, at least one conductive line is cut at an angle relative to the extending direction of the conductive line to produce an angled end face, and an electrical contact landing pad is formed in contact with the angled end face. | 08-15-2013 |
20130250651 | MULTI-FUNCTION RESISTANCE CHANGE MEMORY CELLS AND APPARATUSES INCLUDING THE SAME - Various embodiments comprise apparatuses having a number of memory cells including drive circuitry to provide signal pulses of a selected time duration and/or amplitude, and an array of resistance change memory cells 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. | 09-26-2013 |
20130301336 | 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. | 11-14-2013 |
20130307166 | METHOD FOR FORMING PATTERNS OF DENSE CONDUCTOR LINES AND THEIR CONTACT PADS, AND MEMORY ARRAY HAVING DENSE CONDUCTOR LINES AND CONTACT PADS - A method for forming patterns of dense conductor lines and their contact pads is described. Parallel base line patterns are formed over a substrate. Each of the base line patterns is trimmed. Derivative line patterns and derivative transverse patterns are formed as spaces on the sidewalls of the trimmed base line patterns, wherein the derivative transverse patterns are formed between the ends of the derivative line patterns and adjacent to the ends of the trimmed base line patterns. The trimmed base line patterns are removed. At least end portions of the derivative line patterns are removed, such that the derivative line patterns are separated from each other and all or portions of the derivative transverse patterns become patterns of contact pads each connected with a derivative line pattern. | 11-21-2013 |
20140094026 | METHOD FOR PROVIDING ELECTRICAL CONNECTIONS TO SPACED CONDUCTIVE LINES - An integrated circuit and a method of formation provide a contact area formed at an angled end of at least one linearly extending conductive line. In an embodiment, conductive lines with contact landing pads are formed by patterning lines in a mask material, cutting at least one of the material lines to form an angle relative to the extending direction of the material lines, forming extensions from the angled end faces of the mask material, and patterning an underlying conductor by etching using said material lines and extension as a mask. In another embodiment, at least one conductive line is cut at an angle relative to the extending direction of the conductive line to produce an angled end face, and an electrical contact landing pad is formed in contact with the angled end face. | 04-03-2014 |
20140306172 | INTEGRATED CIRCUIT SYSTEM WITH NON-VOLATILE MEMORY AND METHOD OF MANUFACTURE THEREOF - An integrated circuit system, and a method of manufacture thereof, including: an integrated circuit die having an address switch; a bottom electrode contact, free of halogen constituents, characteristic of a chemical vapor deposition or an atomic layer deposition, and coupled to the address switch; a transition material layer directly on the bottom electrode contact; and a top electrode contact, directly on the transition material layer, for forming a non-volatile memory array on the integrated circuit die. | 10-16-2014 |
20140335694 | 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. | 11-13-2014 |