Abstract: A method of fabricating a solar cell is provided. A saw damage removal process is performed on a silicon substrate. A dry surface treatment is performed to a surface of the silicon substrate on form an irregular surface. A metal-activated selective oxidation is performed to the irregular surface. By using an aqueous solution, the irregular surface is etched to form a nanotexturized surface of the silicon substrate. A dopant diffusion process is performed on the silicon substrate to form a P-N junction. An anti-reflection layer is formed on the silicon substrate. An electrode is formed on the silicon substrate.

Abstract: Provided is a method in which a photodiode layer is formed on a metal interconnection layer, and a hard mask layer is formed on the photodiode layer. Then, a photoresist pattern is formed on the hard mask layer to define a contact hole region, and a first hole is formed in the hard mask layer through an etching process. Next, an ion implantation etching layer is formed in the photodiode layer using the photoresist pattern as an ion implantation mask, and a second hole is formed by etching the ion implantation etching layer. A third hole is formed to expose the metal interconnection by etching a region of the metal interconnection layer corresponding to the second hole.

Abstract: A method of removing carbon doped silicon oxide between metal contacts is provided. A layer of the carbon doped silicon oxide is converted to a layer of silicon oxide by removing the carbon dopant. The converted layer of silicon oxide is selectively wet etched with respect to the carbon doped silicon oxide and the metal contacts, which forms recess between the metal contacts.

Abstract: A pattern forming method is provided, which includes forming, above a substrate, a layer of a diblock copolymer composition containing at least PS and PEO, subjecting the layer to phase separation to obtain a phase-separated layer, thereby forming an easy-to-etch region constituted by PS and having a cylindrical or lamellar configuration extending in a first direction, forming an imprinting resist layer on the phase-separated layer, subjecting the imprinting resist layer to imprinting to form, on the imprinting resist layer, an uneven pattern consisting of projections and recesses extending in a second direction intersecting with the first direction, selectively removing, from the imprinting resist layer, the recesses, thereby leaving only the projections and, at the same time, selectively removing the PS from the phase-separated layer to obtain an etching resistive pattern containing PEO, and etching the substrate using, as a mask, not only the projections but also the etching resistive pattern.

Abstract: Methods of forming metal oxide structures and methods of forming metal oxide patterns on a substrate using a block copolymer system formulated for self-assembly. The metal oxide structures and patterns may be used, for example, as a mask for sublithographic patterning during various stages of semiconductor device fabrication. A block copolymer at least within a trench in the substrate and including at least one soluble block and at least one insoluble block may be annealed to form a self-assembled pattern including a plurality of repeating units of the at least one soluble block laterally aligned with the trench and positioned within a matrix of the at least one insoluble block. The self-assembled pattern may be exposed to a metal oxide precursor that impregnates the at least one soluble block. The metal oxide precursor may be oxidized to form a metal oxide. The self-assembled pattern may be removed to form a pattern of metal oxide lines on the substrate surface.

Abstract: A monolithic, multi-bandgap, tandem solar photovoltaic converter has at least one, and preferably at least two, subcells grown lattice-matched on a substrate with a bandgap in medium to high energy portions of the solar spectrum and at least one subcell grown lattice-mismatched to the substrate with a bandgap in the low energy portion of the solar spectrum, for example, about 1 eV.

Abstract: A method of fabricating a semiconductor device according to one embodiment includes: forming a core material on a workpiece; forming a coating film comprising an amorphous material so as to cover an upper surface and side faces of the core material; crystallizing the coating film by applying heat treatment; forming a sidewall mask by removing the crystallized coating film while leaving a portion thereof located on the side faces of the core material; removing the core material after forming the sidewall mask; and etching the workpiece using the sidewall mask as a mask after removing the core material.

Abstract: A method for controlling chemical dry etching to improve smoothness of an etched surface is disclosed. Ions are implanted into a surface to form a volatilizable compound at a temperature low enough to avoid, reduce, or eliminate formation of three-dimensional structures of the volatilizable compound that might create the roughness at an etched surface of the volatilizable compound. The ions are applied in a sufficient energy to penetrate to a predetermined depth of material that is to be removed from the surface in an etching cycle, and in a sufficient dosage to achieve full formation of the volatilizable compound. The surface of the volatilizable compound is exposed to a gas composition for a time duration sufficient to completely etch the volatilizable compound.

Abstract: Methods of forming a mask for implanting a substrate and implanting using an implant stopping layer with a photoresist provide lower aspect ratio masks that cause minimal damage to trench isolations in the substrate during removal of the mask. In one embodiment, a method of forming a mask includes: depositing an implant stopping layer over the substrate; depositing a photoresist over the implant stopping layer, the implant stopping layer having a density greater than the photoresist; forming a pattern in the photoresist by removing a portion of the photoresist to expose the implant stopping layer; and transferring the pattern into the implant stopping layer by etching to form the mask. The implant stopping layer may include: hydrogenated germanium carbide, nitrogenated germanium carbide, fluorinated germanium carbide, and/or amorphous germanium carbon hydride (GeHX), where X includes carbon. The methods/mask reduce scattering during implanting because the mask has higher density than conventional masks.

Abstract: Ions are implanted into a silicon donor body, defining a cleave plane. A first surface of the donor body is affixed to a receiver element, and a lamina is exfoliated at the cleave plane, creating a second surface of the lamina. There is damaged silicon at the second surface, which will compromise the efficiency of a photovoltaic cell formed from the lamina. A selective etchant, having an etch rate which is positively correlated with the concentration of structural defects in silicon, is used to remove the damaged silicon at the second surface, while removing very little of the relatively undamaged lamina.

Abstract: A semiconductor device manufacturing method includes: providing a laminated member in which at least a first GaAs layer, an InAlGaAs layer and a second GaAs layer are laminated on or above a substrate in this order; and etching the second GaAs layer using the InAlGaAs layer as an etching stopper layer. A ratio of In:Al of the InAlGaAs layer is in a range of approximately 4:6 to approximately 6:4 and a ratio of (In+Al):Ga of the InAlGaAs layer is in a range of approximately 1.5:8.5 to approximately 5:5.

Abstract: Disclosed are one-port and two-port microelectromechanical structures including variable capacitors, switches, and filter devices. High aspect-ratio micromachining is used to implement low-voltage, large value tunable and fixed capacitors, and the like. Tunable capacitors can move in the plane of the substrate by the application of DC voltages and achieve greater than 240 percent of tuning. Exemplary microelectromechanical apparatus comprises a single crystalline silicon substrate, and a conductive structure laterally separated from the single crystalline silicon substrate by first and second high aspect ratio gaps of different size, wherein at least one of the high aspect ratio gaps has an aspect ratio of at least 30:1, and is vertically anchored to the single crystalline silicon substrate by way of silicon nitride.

Abstract: A method for fabricating an integrated circuit includes patterning a mandrel over a layer to be patterned. Dopants are implanted into exposed sidewalls of the mandrel to foam at least two doped layers having at least one undoped region adjacent to the doped layers. The doped layers are selectively etched away to form pillars from the undoped regions. The layer to be patterned is etched using the pillars as an etch mask to form features for an integrated circuit device. A semiconductor device is also disclosed.

Abstract: In a method for producing a thin film chip including an integrated circuit, a semi-conductor wafer having a first surface is provided. At least one cavity is produced under a defined section of the first surface by means of porous silicon. A circuit structure is produced in the defined section. The defined wafer section is subsequently released from the semiconductor wafer by severing local web-like connections, which hold the wafer section above the cavity and on the remaining semiconductor wafer.

Abstract: A method for forming a substrate comprising nanometer-scale pillars or cones that project from the surface of the substrate is disclosed. The method enables control over physical characteristics of the projections including diameter, sidewall angle, and tip shape. The method further enables control over the arrangement of the projections including characteristics such as center-to-center spacing and separation distance.

Abstract: A FinFET having spacers with a substantially uniform profile along the length of a gate stack which covers a portion of a fin of semiconductor material formed on a substrate is provided by depositing spacer material conformally on both the fins and gate stack and performing an angled ion impurity implant approximately parallel to the gate stack to selectively cause damage to only spacer material deposited on the fin. Due to the damage caused by the angled implant, the spacer material on the fins can be etched with high selectivity to the spacer material on the gate stack.

Abstract: A method for processing integrated circuit devices including forming self aligned contact regions. The method includes providing a partially completed semiconductor wafer, the wafer including one or more semiconductor chips, where each of the chips including a plurality of MOS gate structures. Each of the gate structures is formed on a substrate and having a first layer of silicon nitride formed overlying portions including a contact region between the gate structures. Each of the chips has conformal layer of doped silicon glass of a predetermined thickness overlying the silicon nitride layer and the gate structures. The method then applies a plasma etching process to the doped silicon glass to expose a portion of the first silicon nitride layer using an anisotropic etching component to vertically remove portions of the doped silicon glass. A step of cleaning the exposed portion of silicon nitride using an isotropic component is also included.

Abstract: A method of forming an integrated circuit (IC) device feature includes forming an initially substantially planar hardmask layer over a semiconductor device layer to be patterned; forming a first photoresist layer over the hardmask layer; patterning a first set of semiconductor device features in the first photoresist layer; registering the first set of semiconductor device features in the hardmask layer in a manner that maintains the hardmask layer substantially planar; removing the first photoresist layer; forming a second photoresist layer over the substantially planar hardmask layer; patterning a second set of semiconductor device features in the second photoresist layer; registering the second set of semiconductor device features in the hardmask layer in a manner that maintains the hardmask layer substantially planar; removing the second photoresist layer; and creating topography within the hardmask layer by removing portions thereof corresponding to both the first and second sets of semiconductor device

Abstract: A method of fabricating a semiconductor device according to one embodiment includes: forming a porous film above a semiconductor substrate; forming an altered layer by applying alteration treatment to a first pattern region of the porous film up to a predetermined depth; forming a first concave portion by etching a second pattern region to a depth deeper than the predetermined depth, the second pattern region at least partially overlapping the first pattern region of the porous film having the altered layer formed therein; and forming a second concave portion by selectively removing the altered layer from the porous film after forming the first concave portion.

Abstract: A manufacturing method of a semiconductor device includes: irradiating a laser beam on a single crystal silicon substrate, and scanning the laser beam on the substrate so that a portion of the substrate is poly crystallized, wherein at least a part of a poly crystallized portion of the substrate is exposed on a surface of the substrate; and etching the poly crystallized portion of the substrate with an etchant. In this case, a process time is improved.

Abstract: An anisotropic wet etch of a semiconductor layer generates facets joined by a ridge running along the center of a pattern in a dielectric hardmask layer on the semiconductor layer. The dielectric hardmask layer is removed and a conformal masking material layer is deposited. Angled ion implantation of Ge, B, Ga, In, As, P, Sb, or inert atoms is performed parallel to each of the two facets joined by the ridge causing damage to implanted portions of the masking material layer, which are removed selective to undamaged portions of the masking material layer along the ridge and having a constant width. The semiconductor layer and a dielectric oxide layer underneath are etched selective to the remaining portions of the dielectric nitride. Employing remaining portions of the dielectric oxide layer as an etch mask, the gate conductor layer is patterned to form gate conductor lines having a constant width.

Abstract: Monolithic IC/MEMS processes are disclosed in which high-stress silicon nitride is used as a mechanical material while amorphous silicon serves as a sacrificial layer. Electronic circuits and micro-electromechanical devices are built on separate areas of a single wafer. The sequence of IC and MEMS process steps is designed to prevent alteration of partially completed circuits and devices by subsequent high process temperatures.

Abstract: Methods and apparatus for processing a substrate are provided herein. In some embodiments, a method of processing a substrate may include providing a substrate having at least one of a defect or a contaminant disposed on or near a surface of the substrate; and selectively annealing a portion of the substrate with a laser beam in the presence of a process gas comprising hydrogen. The laser beam may be moved over the substrate or continuously, or in a stepwise fashion. The laser beam may be applied in a continuous wave or pulsed mode. The process gas may further comprise an inert gas, such as, at least one of helium, argon, or nitrogen. A layer of material may be subsequently deposited atop the annealed substrate.

Abstract: The invention relates to a method of fabricating an integrated circuit, including the steps of providing at least one layer; performing a first implantation step, wherein particles are implanted into the layer under a first direction of incidence; performing a second implantation step, wherein particles are implanted into the layer under a second direction of incidence which is different from the first direction of incidence; performing a removal step, wherein the layer is partially removed depending on the local implant dose generated by the first and the second implantation step.

Abstract: A method for forming a field effect transistor (FET) device includes forming a gate conductor over a semiconductor substrate; forming a source region, the source region having a source extension that overlaps and extends under the gate conductor; and forming a drain region, the drain region having a drain extension that overlaps and extends under the gate conductor at selected locations along the width of the gate; and the drain region further comprising a plurality of recessed areas corresponding to areas where the drain extension does not overlap and extend under the gate conductor, wherein the plurality of recessed areas is formed only in the drain region.

Abstract: A method for manufacturing a probe structure is disclosed. In accordance with the method, two semiconductor substrates having different crystal directions are bonded and selectively etched utilizing an etch selectivity due to the different crystal directions to form a probe tip region and a probe beam region. A cantilever structure for a probe card is formed by filling the probe tip region and the probe beam region with a conductive material.

Abstract: Methodologies and gate etching processes are presented to enable the fabrication of gate conductors of semiconductor devices, such as NFETs and/or PFETs, which are equipped with nano-channels. In one embodiment, a sacrificial spacer of equivalent thickness to the diameter of the gate nano-channel is employed and is deposited after patterning the gate conductor down to the gate dielectric. The residue gate material that is beneath the nano-channel is removed utilizing a medium to high density, bias-free, fluorine-containing or fluorine- and chlorine-containing isotropic etch process without compromising the integrity of the gate. In another embodiment, an encapsulation/passivation layer is utilized. In yet further embodiment, no sacrificial spacer or encapsulation/passivation layer is used and gate etching is performed in an oxygen and nitrogen-free ambient.

Abstract: A CMOS FinFET device and a method of manufacturing the same using a three dimensional doping process is provided. The method of forming the CMOS FinFET includes forming fins on a first side and a second side of a structure and forming spacers of a dopant material having a first dopant type on the fins on the first side of the structure. The method further includes annealing the dopant material such that the first dopant type diffuses into the fins on the first side of the structure. The method further includes protecting the first dopant type from diffusing into the fins on the second side of the structure during the annealing.

Abstract: Treatment of a semiconductor wafer employs: a) position-dependent measuring of a parameter characterizing the semiconductor wafer to determine a position-dependent value of the parameter over an entire surface of the semiconductor wafer, b) oxidizing the entire surface of the semiconductor wafer under the action of an oxidizing agent with simultaneous exposure of the entire surface, the oxidation rate and thus the thickness of the resulting oxide layer dependent on the light intensity at the surface of the semiconductor wafer, and c) removing of the oxide layer, the light intensity in step b) predefined in a position-dependent manner such that differences in the position-dependent values of the parameter measured are reduced by the position-dependent oxidation rate resulting in step b) and subsequent removal of the oxide layer in step c).

Abstract: An etching technique for the fabrication of thin (Al, In, Ga)N layers. A suitable template or substrate is selected and implanted with foreign ions over a desired area to create ion implanted material. A regrowth of a device structure is then performed on the implanted template or substrate. The top growth surface of the template is bonded to a carrier wafer to created a bonded template/carrier wafer structure. The substrate is removed, as is any residual material, to expose the ion implanted material. The ion implanted material on the bonded template/carrier wafer structure is then exposed to a suitable etchant for a sufficient time to remove the ion implanted material.

Abstract: One possible embodiment is a method of manufacturing a structure on or in a substrate with the following steps a) positioning at least one spacer structure by a spacer technique on the substrate, b) using at least one of the groups of the spacer structure and a structure generated by the spacer structure as a mask for a subsequent particle irradiation step for generating a latent image in the substrate c) using the latent image for further processing the substrate.

Abstract: A semiconductor device having a saddle fin gate and a method for manufacturing the same are presented. The semiconductor device includes a semiconductor substrate, an isolation structure, and gates. The semiconductor substrate is defined with first grooves in gate forming areas. The isolation structure is formed in the semiconductor substrate and is defined with second grooves which expose front and rear surfaces of the gate forming areas. The gates are formed within the first grooves in the gate forming areas. Gates are also formed in the second grooves of the isolation structure to cover the exposed front and rear surfaces of the gate forming areas. The second grooves are wider at the lower portions that at the upper portions.

Abstract: 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 NH3 and HF and heated, to substantially uniformly remove the silicon oxide. A method of removing an exposed sacrificial layer without substantially removing exposed isolation regions using the gaseous mixture of NH3 and HF and heat is also disclosed, as is an intermediate semiconductor device structure that includes a semiconductor substrate, a sacrificial layer overlying the semiconductor substrate, a diffusion barrier overlying the sacrificial layer, and exposed isolation regions.

Abstract: A semiconductor device is formed by providing a substrate and forming a semiconductor-containing layer atop the substrate. A mask having a plurality of openings is then formed atop the semiconductor-containing layer, wherein adjacent openings of the plurality of openings of the mask are separated by a minimum feature dimension. Thereafter, an angled ion implantation is performed to introduce dopants to a first portion of the semiconductor-containing layer, wherein a remaining portion that is substantially free of dopants is present beneath the mask. The first portion of the semiconductor-containing layer containing the dopants is removed selective to the remaining portion of semiconductor-containing layer that is substantially free of the dopants to provide a pattern of sublithographic dimension, and the pattern is transferred into the substrate to provide a fin structure of sublithographic dimension.

Abstract: Embodiments of this method improve the results of a chemical mechanical polishing (CMP) process. A surface is implanted with a species, such as, for example, Si, Ge, As, B, P, H, He, Ne, Ar, Kr, Xe, and C. The implant of this species will at least affect dishing, erosion, and polishing rates of the CMP process. The species may be selected in one embodiment to either accelerate or decelerate the CMP process. The dose of the species may be varied over the surface in one particular embodiment.

Abstract: A semiconductor device comprises a semiconductor layer including a plurality of paralleled linear straight sections extending in a first direction. The layer also includes a plurality of connecting sections each having a width in the first direction sufficient to form a wire-connectable contact therein and arranged to connect between adjacent ones of the straight sections in a second direction. The connecting sections have respective ends formed aligned with a first straight line parallel to the second direction.

Abstract: A method for fabricating a integrated circuit with improved performance is disclosed. The method comprises providing a substrate; forming a hard mask layer over the substrate; forming protected portions and unprotected portions of the hard mask layer; performing a first etching process, a second etching process, and a third etching process on the unprotected portions of the hard mask layer, wherein the first etching process partially removes the unprotected portions of the hard mask layer, the second etching process treats the unprotected portions of the hard mask layer, and the third etching process removes the remaining unprotected portions of the hard mask layer; and performing a fourth etching process to remove the protected portions of the hard mask layer.

Abstract: Described herein are embodiments of a slurry used for the chemical mechanical polishing a substrate that includes aluminum or an aluminum alloy features having a width of less than 1 um. The slurry includes a precipitated silica abrasive having a diameter of less than or equal to 100 nm and a chelating buffer system comprising citric acid and oxalic acid to provide a pH of the slurry in the approximate range of 1.5 and 4.0.

Abstract: A method for manufacturing an organic thin film transistor substrate comprising forming a gate electrode on a substrate, forming a gate insulating layer on the gate electrode, defining a channel region on the gate insulating layer between a source electrode and a drain electrode, neutralizing the channel region, forming a bank insulating layer on the source electrode and the drain electrode, and forming an organic semiconductor layer in a region prepared by the bank insulating layer.

Abstract: A method of making a device includes forming a first photoresist layer over an underlying layer, patterning the first photoresist layer to form a first photoresist pattern, rendering the first photoresist pattern insoluble to a solvent, forming a second photoresist layer over the first photoresist pattern, patterning the second photoresist layer to form a second photoresist pattern over the underlying layer, and etching the underlying layer using both the first and the second photoresist patterns as a mask.

Abstract: A field effect transistor (FET) device includes a gate conductor formed over a semiconductor substrate, a source region having a source extension that overlaps and extends under the gate conductor, and a drain region having a drain extension that overlaps and extends under the gate conductor only at selected locations along the width of the gate conductor.

Abstract: A unipolar semiconductor laser is provided in which an active region is sandwiched in a guiding structure between an upper and lower cladding layer, the lower cladding layer being situated on a semiconducting substrate. The unipolar semiconductor laser comprises a raised ridge section running from end to end between end mirrors defining the laser cavity. The ridge section aids in optical and electrical confinement. The ridge waveguide is divided in a plurality of cavity segments (at least two). Lattice structures can be arranged on and/or adjacent to these cavity segments. Each cavity segment is in contact with upper metallic electrodes. A metallic electrode coupled to the bottom surface of the semiconducting substrate facilitates current injection through the device.

Abstract: In a method for manufacturing a display device having a light emitting element, a first base insulating film, a second base insulating film, a semiconductor layer, and a gate insulating film are formed in this order over a substrate. A gate electrode is formed over the gate insulating film to overlap with at least a part of the semiconductor layer, and a portion to be a pixel portion of the gate insulating film and the second base insulating film is doped with at least one conductive type impurities. An opening portion is formed by selectively etching the gate insulating film and second base insulating film that are each doped with impurities. The first base insulating film is exposed in a bottom face of the opening portion. Subsequently, an insulating film is formed to cover the opening portion, the gate insulating film, and the gate electrode, and a light emitting element is formed over the insulating film to overlap with at least a part of the opening portion.

Abstract: To form a semiconductor device, an insulating layer is formed over a conductive region and a pattern transfer layer is formed over the insulating layer. The pattern transfer layer is patterned in the reverse tone of a layout of recesses to be formed in the insulating layer such that the pattern transfer layer remains over regions where the recesses are to be formed. A mask material is formed over the insulating layer and is aligned with the pattern transfer layer. Remaining portions of the pattern transfer layer are removed and recesses are etched in the insulating layer using the mask material as a mask.

Abstract: A method of fabricating a thickness of silicon material includes providing a silicon ingot material having a surface region and introducing a plurality of particles having an energy of about 1-5 MeV through the surface region to a depth to define a cleave region and a thickness of detachable material between the cleave region and the surface region. Additionally, the method includes processing the silicon ingot material to free the thickness of detachable material at a vicinity of the cleave region and causing formation of a free-standing thickness of material characterized by a carrier lifetime about 10 microseconds and a thickness ranging from about 20 microns to about 150 microns with a thickness variation of less than about five percent. Furthermore, the method includes treating the free-standing thickness of material using a thermal treatment process to recover the carrier lifetime to about 200 microseconds and greater.

Abstract: A method of treating a substrate comprises depositing silicon oxycarbide on the substrate and removing the silicon oxycarbide from the substrate. The silicon oxycarbide on the substrate is decarbonized by exposure to an energized oxygen-containing gas that heats the substrate and converts the layer of silicon oxycarbide into a layer of silicon oxide. The silicon oxide is removed by exposure to a plasma of fluorine-containing process gas. Alternatively, the remaining silicon oxide can be removed by a fluorine-containing acidic bath. In yet another version, a plasma of a fluorine-containing gas and an oxygen-containing gas is energized to remove the silicon oxycarbide from the substrate.

Abstract: A process including forming a silicon layer over a semiconductor wafer having features thereon and then selectively ion implanting in the silicon layer to form ion implanted regions. The step of selectively ion implanting is repeated as many times as necessary to obtain a predetermined number and density of features. Thereafter, the silicon layer is etched to form openings in the silicon layer that were formerly occupied by the ion implanted regions. The opened areas in the silicon layer form a mask for further processing of the semiconductor wafer.

Abstract: Methods of forming a mask for implanting a substrate and implanting using an implant stopping layer with a photoresist provide lower aspect ratio masks that cause minimal damage to trench isolations in the substrate during removal of the mask. In one embodiment, a method of forming a mask includes: depositing an implant stopping layer over the substrate; depositing a photoresist over the implant stopping layer, the implant stopping layer having a density greater than the photoresist; forming a pattern in the photoresist by removing a portion of the photoresist to expose the implant stopping layer; and transferring the pattern into the implant stopping layer by etching to form the mask. The implant stopping layer may include: hydrogenated germanium carbide, nitrogenated germanium carbide, fluorinated germanium carbide, and/or amorphous germanium carbon hydride (GeHX), where X includes carbon. The methods/mask reduce scattering during implanting because the mask has higher density than conventional masks.

Abstract: A method for processing at least one wall of an opening formed in a silicon substrate, successively including the steps of implanting fluorine atoms into an upper portion of the wall of the opening, performing an oxidization step, and applying a specific processing to at least a portion of the non-implanted portion of the opening.

Abstract: A self-aligned pitch fragmentation method for manufacturing an integrated circuit includes forming openings in a first layer, wherein the openings uncover first sections of a second layer arranged below the first layer. The first sections of the second layer are removed. The first layer is shrunk and the openings are expanded to form a first mask from the first layer, wherein the first mask exposes second sections and covers third sections of the second layer. The etch properties of the second sections are altered selectively to the third sections to facilitate the self-aligned pitch fragmentation method.