Abstract: Methods of preparing pre-engineered surfaces using various nanolithography techniques to generate, isolate, and multiply homogeneous cell populations. Surfaces can be treated by etching before exposure to biological systems like cells. Stem cell applications are described.

Abstract: Provided are a master recording medium and a method of manufacturing the master recording medium. The master recording medium includes: a plate; and a magnetic layer which is formed on the plate for magnetically transferring of a servo pattern that is to be formed on a magnetic recording medium. The method of manufacturing a master recording medium includes: engraving a polymer layer by nano imprinting to form an engraved pattern corresponding to a servo pattern to be formed on a magnetic recording medium; forming a magnetic layer which fills in the engraved pattern of the polymer layer; forming a back plate layer on the magnetic layer; and performing processing to expose the servo pattern on a surface of the magnetic layer that is opposite a surface of the magnetic layer on which the back plate layer is formed.

Abstract: Amorphous inorganic nitrides are used as release layers on templates for nanoimprint lithography. Such a layer facilitates the release of a template from a cured, hardened composition into which the template has transferred a pattern, by reducing the adhesion energy between the release layer and the cured, hardened composition. The release layer may include one or more metallic or semiconductor elements such as Al, Mn, B, Co, Ti, Ta, W and Ge.

Abstract: A UV nanoimprint lithography process and its apparatus that are able to repeatedly fabricates nanostructures on a substrate (wafer, UV-transparent plate) by using a stamp that is as large as or smaller than the substrate in size are provided. The apparatus includes a substrate chuck for mounting the substrate; a stamp made of UV-transparent materials and having more than two element stamps, wherein nanostructures are formed on the surface of each element stamp; a stamp chuck for mounting the stamp; a UV lamp unit for providing UV light to cure resist applied between the element stamps and the substrate; a moving unit for moving the substrate chuck or the stamp chuck to press the resist with the element stamps and substrate; and a pressure supply unit for applying pressurized gas to some selected regions of the substrate to help complete some incompletely filled element stamps.

Abstract: In accordance with the invention, step-and-repeat imprint lithography is effected by applying balanced pressing forces from both sides of a substrate. The pressing forces are substantially equal in amplitude and opposite in direction. With the pressing forces thus balanced, the fixture that steps and holds the substrate does not bear the load of imprinting. The balance allows use of a high resolution aligning stage to carry the substrate and to maintain high accuracy of positioning without being shifted by change of load. With this method, sufficient imprint pressure can be used to obtain high quality patterning, a thin and uniform residual layer, and a high fidelity pattern.

Abstract: An imprint system has a design data storing section which stores template information and remaining film thickness set value information, a vaporization-to-be-compensated storing section which stores a plurality of distributions of applied amounts for compensating vaporization, an arithmetic section which calculates a distribution of an applied amount for filling a pattern based upon the template information, calculates a distribution of an applied amount for forming a remaining film thickness based upon the remaining film thickness set value information, calculates a pattern density of the template from the template information, extracts a distribution of an applied amount for compensating vaporization, corresponding to this pattern density, from the vaporization-to-be-compensated storing section, and adds up this extracted distribution of an applied amount for compensating vaporization, the distribution of an applied amount for filling a pattern, and the distribution of an applied amount for forming a remai

Abstract: A process using the nanoimprint technique to form the diffraction grating for the DFB-LD is disclosed. The process includes (a) coating a resist for the EB exposure on a dummy substrate, (b) irradiating the resist as varying the acceleration voltage, (c) forming a resist pattern by developing the irradiated resist, (d) coating the SOG film on the patterned resist, (e) attaching the silica substrate on the cured SOG film, and (f) removing the dummy substrate with the resist from the SOG film and the silica substrate. Using the mold thus formed, the diffraction grating for the DFB-LD is formed by the nanoimprint technique.

Abstract: In one aspect of the invention, systems, methods, and devices are provided for creating microfluidic and nanofluidic structures. In some embodiments, such systems, methods, and devices are used to create features with high aspect ratios in lab cards.

Abstract: A process for producing a patterned structure comprises imprinting a first pattern by pressing a stamper having a projection-depression configuration on the surface against an imprint-work layer, and imprinting a second pattern by displacing relatively the stamper from the position of the first pattern to another position on the imprint-work layer and then pressing the stamper against the imprint-work layer.

Abstract: Disclosed herein is a method for transferring a pattern of minute dents and projections to an energy ray-setting resin layer coated on a substrate plate by pressing a master pattern on a transfer mold, followed by irradiation of energy rays. The pattern transfer method comprises the steps of pressing a master pattern on a transfer mold against the resin layer under a predetermined imprinting pressure, irradiating the resin layer under the imprinting pressure with energy rays, interrupting the irradiation of energy rays and at the same time cancelling application of the imprinting pressure and holding the resin layer and the transfer mold in a non-pressed state to relieve the resin layer of internal stresses, and recommencing irradiation of the resin layer with energy rays to complete hardening of the resin layer which is held in contact with the transfer mold in a non-pressed state.

Abstract: A nano-imprinting process is described, comprising: providing a substrate including an imprinting material layer covering a surface of the substrate; providing a mold including protruding features set on a surface of the mold covered with an anti-adhesion layer; forming a transferring material layer on a top surface of each protruding feature; embedding the transferring material layer into a first portion of the imprinting material layer; removing the mold and separating the mold and the transferring material layer simultaneously to transfer the transferring material layer into the first portion of the imprinting material layer and to expose a second portion of the imprinting material layer; using the transferring material layer as a mask to remove the second portion of the imprinting material layer and a portion of the substrate; and removing the first portion of the imprinting material layer and the transferring material layer.

Abstract: The invention relates to a method for production of a surface-structured substrate, comprising the steps: (i) production of a first substrate, nanostructured with inorganic nanoclusters on at least one surface, (ii) application of a substrate material for a second substrate, different from the first material to the nanostructured surface of the first substrate as obtained in step (i) and (iii) separation of the first substrate from the second substrate of step (ii), including the inorganic nanoclusters to give a second substrate nanostructured with the nanoclusters.

Abstract: Wound dressing assemblies and methods of producing the wound dressing assemblies. The wound dressing assemblies various comprise individual layers of nanomaterials that have been formed according to an electrospinning process. Each of the layers can have different characteristics and qualities. The invention also provides guidance in selecting materials to form a wound dressing assembly, as well as possible adaptations to the electrospinning process to provide different characteristics for particular materials.

Abstract: A method for forming an electronic device having a multilayer structure, comprising: embossing a surface of a substrate so as to depress first and second regions of the substrate relative to at least a third region of the substrate; depositing conductive or semiconductive material from solution onto the first and second regions of the substrate so as to form a first electrode on the first region and a second electrode on the second region, wherein the electrodes are electrically insulated from each other by the third region.

Abstract: Engineered proteins are used in the assembly of two-dimensional and three-dimensional nanostructure assemblies, based on systematic design and production of protein node structures that can be interconnected, for example, with streptavidin or streptavidin-incorporating struts to produce structures with defined dimensions and geometry. Nanostructure assemblies having utility as functional devices or as resists for the patterning of substrates have architectures including polygons, polyhedra, two-dimensional lattices, and three-dimensional lattices.

Abstract: A light-transmitting mold structure having a mold pattern corresponding to a portion to form a pattern by nanoimprint and a conductive film pattern corresponding to a portion to form a pattern by nonadiabatic near-field exposure is used to irradiate UV light from a back surface of the mold structure and to perform nonadiabatic near-field light exposure in an imprint process so that all patterns having various sizes for simulating various designs can be faithfully transferred by a single imprint process (imprint & UV exposure).

Abstract: An imprinting method is disclosed that includes applying an imprinting force to a template to cause the template to contact an imprintable medium on a target region of a first surface of a substrate to form an imprint in the medium, during application of the imprinting force, applying a compensating force to a second surface of the substrate which is opposite to the first surface so as to reduce deformation of the substrate caused by the application of the imprinting force, and separating the template from the imprinted medium.

Abstract: The present invention is directed to novel methods of imprinting substrate-supported or freestanding structures at low cost, with high pattern transfer yield, and using low processing temperature. Such methods overcome many of the above-described limitations of the prior art. Generally, such methods of the present invention employ a sacrificial layer of film.

Abstract: A method of manufacturing a plastic surface with superhydrophobicity and high transparency is disclosed. In this method, a thermal nanoimprinting mold method is used to form a plurality of sub-20 nm nanograss structure on a surface of a cyclic-olefin copolymer (COC) material, so that the surface can have superhydrophobicity and high transparency at the same time.

Abstract: The invention relates to an optical filter and a method for its production, and to a device for the examination of the spectral and spatial distribution of an electromagnetic radiation irradiated from an object. The invention is based on the task of providing an optical filter of the above described type that is inexpensive to produce, which can be used to detect a plurality of wavelengths, in which, however, tuning of the DBR mirrors by means of displacement is not necessary. Furthermore, a method for the production of such a filter is provided.

Abstract: A pattern (P) is transferred onto an optical article (1) in the form of one or more portions of a transferable material (3, 4b) retained by a layer of latex (2). The portion or portions of transferable material are applied with a stamp after the layer of latex has been formed on the article and before the latex is dry. By using latex as the adhesive material, the nature of the transferable material may vary widely. Such a method is particularly suitable for producing patterns such as holograms on optical lenses, especially ophthalmic lenses. The layer of latex may also protect the product against shocks which may subsequently be received.

Abstract: Disclosed is a process for the production of a fine structure through nanoimprinting a photocurable resin composition. The process includes the steps of (1) forming a photocurable resin composition for nanoimprint into a film on a support and transferring a pattern to the film by pressing the film with a nanostamper at a pressure of 5 to 100 MPa, in which the photocurable resin composition contains a curable compound component including at least one cationically polymerizable compound and/or at least one free-radically polymerizable compound; and (2) curing the patterned film to obtain the fine structure.

Abstract: A method realizes a multispacer structure including an array of spacers having same height. The method includes realizing, on a substrate, a sacrificial layer of a first material; b) realizing, on the sacrificial layer, a sequence of mask spacers obtained by SnPT, which are alternately obtained in at least two different materials; c) chemically etching one of the two different materials with selective removal of the mask spacers of this etched material and partial exposure of the sacrificial layer; d) chemically and/or anisotropically etching the first material with selective removal of the exposed portions of the sacrificial layer; e) chemically etching the other one of the two different materials with selective removal of the mask spacers of this etched material and obtainment of the multispacer structure.

Abstract: A template chuck includes multiple zones to provide 1) an imprint bend optimized to provide high curvature and provide contact at middle radius of substrate and/or, 2) separation bend zone with an increased free span zone and high crack angle.

Abstract: An imprint system has a design data storing section which stores template information and remaining film thickness set value information, a vaporization-to-be-compensated storing section which stores a plurality of distributions of applied amounts for compensating vaporization, an arithmetic section which calculates a distribution of an applied amount for filling a pattern based upon the template information, calculates a distribution of an applied amount for forming a remaining film thickness based upon said remaining film thickness set value information, calculates a pattern density of the template from the template information, extracts a distribution of an applied amount for compensating vaporization, corresponding to this pattern density, from the vaporization-to-be-compensated storing section, and adds up this extracted distribution of an applied amount for compensating vaporization, the distribution of an applied amount for filling a pattern, and the distribution of an applied amount for forming a rema

Abstract: A nanoimprint resist includes a hyperbranched polyurethane oligomer (HP), a perfluoropolyether (PFPE), a methylmethacrylate (MMA), and a diluent solvent. A method of a nanoimprint lithography is also provided.

Abstract: A nanoimprint resist that includes a hyperbranched polyurethane oligomer (HP), a perfluoropolyether (PFPE), a methylmethacrylate (MMA), a diluent solvent and a photo initiator. A method of a nanoimprint lithography is also provided.

Abstract: Nanoscale patterns prepared by lithography are used to direct the self-assembly of amphiphilic molecules to form patterned nanosubstrates having a desired distribution of chemical functional moieties. These patterns can be fabricated over a large area and require no special limitations on the chemistry the assembled amphiphiles. Hydrophilic/hydrophobic patterns can be created and used to direct the deposition of a single functional component to specific regions of the surface or to selectively assemble polymer blends to desired sites in a one step fashion with high specificity and selectivity. The selective deposition of functional moieties on a patterned surface can be based on electrostatic forces, hydrogen bonding, or hydrophobic interactions.

Abstract: The present invention provides a method that features improved wetting characteristics while allowing preferential adhesion and release characteristics with respect to a substrate and a mold having imprinting material disposed therebetween. The method includes coating a surface of the mold with a volume of surfactant containing solution. The surfactant in the solution includes a hydrophobic component consisting essentially of a plurality of fluorine-containing molecules. The distribution of the plurality of the fluorine atoms in the fluorine-containing molecules, as well as the fluorine-containing molecules throughout the volume provides a desired contact angle with respect to a polymerizable composition disposed on the substrate. The contact angle is in a range of 50° or less.

Abstract: An imprinting apparatus and an imprinting method that prevents movement of an imprinting mold during an imprinting process. The imprinting method includes coating a resin on a substrate; aligning an imprinting mold on the resin; temporarily securing the imprinting mold on the substrate; pressing the imprinting mold; hardening the resin; and detaching the imprinting mold.

Abstract: One embodiment of the present invention provides a photosensitive organo-metallic hybrid material which functions as both a structural material and a photoresist material. More specifically, this photosensitive organo-metallic hybrid material includes an organo-metallic compound comprised of at least one unsaturated double bond. The photosensitive organo-metallic hybrid material also includes a cross-linking agent comprised of at least two unsaturated double bonds capable of cross-linking the organo-metallic compound to form an organo-metallic hybrid material. Additionally, the photosensitive organo-metallic hybrid material includes a photoactive compound capable of absorbing exposure light during a photolithography process to form the photosensitive organo-metallic hybrid material.

Abstract: A method of depositing material upon a substrate features filling recesses of a substrate with liquid and removing material present on the substrate, outside of the recesses using fluid, i.e., apply a vacuum of a jet of fluid. To that end, one method of the present invention includes depositing a measure of liquid upon a surface of a substrate having a recess formed therein to ingress into a volume of the recess with a portion of the liquid. A quantity of the liquid is disposed upon regions of the surface proximate to the recess. Thereafter, the quantity of liquid is removed while maintaining the portion within the volume. In this manner, the portion may be transferred onto an additional substrate. More specifically, the portion may be placed in contact with a layer of flowable material and cross-linking therewith by exposing the liquid and the flowable material to actinic radiation.

Abstract: A method for manufacturing a plate-like structure, the method including a step of transferring concave and convex patterns on a master to a surface of a transferred substrate by sandwiching the master provided with the concave and convex patterns and the transferred substrate, between a press surface of a hollow cylindrical upper and a press surface of a lower mold, and pressurizing central parts of the upper and lower molds to apply pressure to the master and the transferred substrate, wherein a compressive load imposed on inner peripheral portions of the upper and lower molds is blocked and distributed toward outer peripheries of the upper and lower molds.

Abstract: The present invention relates to a method of patterning molecules on a substrate using a micro-contact printing process, to a substrate produced by said method and to uses of said substrate. It also relates to a device for performing the method according to the present invention.

Abstract: Nanoimprint lithography templates and methods of fabricating semiconductor devices using the nanoimprint lithography templates are provided. The nanoimprint lithography template includes a transparent substrate having a first refractive index, a stamp pattern on a surface on the transparent substrate and having inclined sidewalls, and a coating layer formed on the inclined sidewalls of the stamp pattern, the coating layer having a second refractive index higher than the first refractive index.

Abstract: An improved lithographic alignment method, system, and template. The method includes creating, within a lithographic subfield, subsequent-layer features which are intentionally offset from their respective previous-layer features, where the intentional offset may vary in magnitude and direction from one subfield to the next. The system includes an imprint lithographic machine and first and second lithography templates where the templates are adapted to enable the machine to form first and second features, respectively, and where a second feature is configured to be deliberately offset from a corresponding first feature. The template set includes at least two templates, one having features which are deliberately offset from corresponding features of another template. Also, a method of manufacturing such a template set.

Abstract: A nanoimprint mold includes a substrate having at least one substantially non-transferable feature and at least one transferable feature defined at different portions thereon. Methods for forming the same are also disclosed.

Abstract: A method of patterning a substrate comprising first and second fields with a template, the template having a mold and a plurality of alignment forming areas and a plurality of template alignment marks, the method comprising: positioning a material on the first field of the substrate and a plurality of regions of the substrate, the plurality of regions laying outside of the first and second fields; positioning the mold and the substrate such that a desired spatial relationship between the mold and the first field of the substrate is obtained to define a pattern in the material on the first field of the substrate while concurrently defining a plurality of substrate alignment marks with the material in the plurality of regions of the substrate in superimposition with the plurality of alignment forming areas of the template; positioning a material on the second field of the substrate; and positioning the mold and the substrate to obtain a desired spatial relationship between the plurality of template alignment ma

Abstract: A laser diode having nano patterns is disposed on a substrate. A first conductive-type clad layer is disposed on the substrate, and a second conductive-type clad layer is disposed on the first conductive-type clad layer. An active layer is interposed between the first conductive-type clad layer and the second conductive-type clad layer. Column-shaped nano patterns are arranged at a surface of the second conductive-type clad layer to form a laser diode such as a distributed feedback laser diode.

Abstract: There is disclosed an imprinted polymer support for solid phase organic synthesis (SPOS). The polymer support being obtainable from a method that comprises providing a substrate and a mold, the mold having a defined surface pattern. A composition is placed between the defined surface pattern of the mold and the substrate. The composition comprises a polymerisation medium with at least one functional monomer and a free radical initiator. The composition is polymerised to form an array of polymer imprints adhered to the substrate.

Abstract: The invention comprises methods of patterning a plurality of substrates, and imprint templates used in imprint lithography. In one implementation, a method of patterning a plurality of substrates includes providing an imprint template having a plurality of spaced features. A first substrate is imprinted with the imprint template effective to form a plurality of recesses into the first substrate from the spaced features. After imprinting the first substrate, an elevationally outermost portion of the spaced features is removed effective to reduce elevation of the spaced features. After the removing, a second substrate is imprinted with the imprint template using the elevation-reduced spaced features effective to form a plurality of recesses into the second substrate from the elevation-reduced spaced features. Other aspects and implementations are contemplated.

Abstract: An imprint template configured to imprint an imprintable medium by an imprint lithography process is disclosed, the imprint template having a pattern with a pattern density corresponding to a volume of imprintable medium used to substantially fill pattern features per unit area of a contact face of the imprint template, wherein adjacent regions of the pattern on the imprint template contact face, each of which will provide different functionality once imprinted onto a substrate, have substantially the same pattern density, have differences in pattern density which are minimized, or differences in pattern density which are maintained below a maximum.

Abstract: A method of fabricating an array substrate for a liquid crystal display device comprises forming a gate line, a data line that crosses the gate line and a thin film transistor connected to the gate line and the data line on a substrate, and forming an organic insulating material layer on the gate line, the data line and the thin film transistor. The organic insulating material layer has photo curability, flexibility and dynamic stability. The method further comprises forming a passivation layer that has a drain contact hole from the organic insulating material layer by using a stamp that has a convex portion. The drain contact hole exposes a drain electrode of the thin film transistor. The method also comprises forming a pixel electrode on the passivation layer. The pixel electrode is connected to the drain electrode through the drain contact hole.

Abstract: An imprint process comprising coating a selected surface of a micropatterned template with a release composition having a basic reactive moiety; wherein the template is transparent to UV radiation; imprinting the template onto a photocationically curable composition; curing the UV curable composition to form an imprinted composition, wherein the release composition having a basic reactive moiety is effective to locally inhibit curing of the composition at an interface between the template and the imprinted composition; and releasing the template from the imprinted composition.

Abstract: A system, method, and apparatus for forming a high quality master pattern for patterned media, including features to support servo patterns, is disclosed. Block copolymer self-assembly is used to facilitate the formation of a track pattern with narrower tracks. E-beam lithography forms a chemical contrast pattern of concentric rings, where the spacing of the rings is equal to an integral multiple of the target track pitch. The rings include regions within each servo sector header where the rings are offset radially by a fraction of a track pitch. Self-assembly is performed to form a new ring pattern at the target track pitch on top of the chemical contrast pattern, including the radial offsets in the servo sector headers. When this pattern is transferred to disks via nanoimprinting and etching, it creates tracks separated by nonmagnetic grooves, with the grooves and tracks including the radial offset regions.

Abstract: A nanostructure without bulges and a method of fabricating the nanostructure are provided. The method includes forming a nanopattern on a surface of a polymer, allowing the surface of the polymer with the nanopattern to come into contact with a predetermined solvent, and applying an external stimulus to the surface of the polymer in contact with the solvent to remove bulges around the nanopattern formed during formation of the nanopattern. Accordingly, the bulges of the nanostructure where the nanopattern is formed may be removed at a low cost and in a simple manner.

Abstract: Methods for fabricating nanoscale features are disclosed. One technique involves depositing onto a substrate, where the first layer may be a silicon layer and may subsequently be etched. A second layer and third layer may be deposited on the etch first layer, followed by the deposition of a silicon cap. The second and third layer may be etched, exposing edges of the second and third layers. The cap and first layer may be removed and either the second or third layer may be etched, creating a nanoscale pattern.

Abstract: A nanoimprinting configuration includes a UV light diffuser that randomizes a collimated UV light beam so as to diffuse the shadowing effect from any defect object that resides in the UV optical path. In addition, a combination center circular pad and outer ring-shaped pad form a donut-shaped “non-contact” area between the two pad pieces. The size and shape of the two pad combination are designed to avoid direct gel pad contact above the patterned imprint zone on the disk substrate. The purpose of the gel pad, non-contact configuration is to eliminate any possible surface deformation incurred along the loading column and thereby avoid the elastic propagation of any deformations to the stamper resist surface.

Abstract: The present invention provides a flexible nanoimprint mold which can fabricate sub-15 nm ultra fine structures on either planar or curved substrates. The mold comprises a top ultra-thin rigid layer of imprint patterning features and a bottom thick flexible layer of polymer elastomer. The two distinct layers are preferably integrated via chemically bonding. The top layer of the mold enables a sub-15 nm resolution of pattern fabrication and the bottom layer affords a conformal contact to planar or curved surface of substrates. The methods for fabricating the same are disclosed.

Abstract: Described are imprint lithography templates, methods of forming and using the templates, and a template holder device. An imprint lithography template may include a body with a plurality of recesses on a surface of the body. The body may be of a material that is substantially transparent to activating light. At least a portion of the plurality of recesses may define features having a feature size less than about 250 nm. A template may be formed by obtaining a material that is substantially transparent to activating light and forming a plurality or recesses on a surface of the template. In some embodiments, a template may further include at least one alignment mark. In some embodiments, a template may further include a gap sensing area. An imprint lithography template may be used to form an imprinted layer in a light curable liquid disposed on a substrate. During use, the template may be disposed within a template holder.