Abstract: Methods described include placing a sensor system over a substrate positioned on a chuck. The sensor system generates a beam of optical energy towards the substrate and is configured to receive optical energy deflected from the substrate. The sensor system generates sensor signals in response to variations in received optical energy from the substrate and the chuck.

Abstract: Two-stage imprinting techniques capable of protecting fine patterned features of an imprint lithography template are herein described. In particular, such techniques may be used during fabrication of recessed high-contrast alignment marks for preventing deposited metal layers from coming into contact with fine features etched into the template.

Abstract: A loading unit, surface scanning module, and an imprint module may be integrated into a single tool. Template may be loaded on loading unit and positioned within imprint module. Substrate may then be loaded on loading unit and scanned defects using surface scanning module. If substrate passes inspection by surface scanning module, substrate may be positioned imprint module where formable material may be dispensed thereon and imprinted. The imprinted substrate may then be unloaded from imprinting module.

Abstract: A template is treated to provide a surfactant rich region and a surfactant depleted region. A contact angle at the surfactant rich region may be greater than, less than, or substantially similar to a contact angle of the surfactant depleted region.

Abstract: A solid layer is formed by applying a multiplicity of discrete portions of a fluid composition onto a surface of an imprint lithography substrate, and allowing the discrete portions of the composition to spontaneously spread on the surface of the substrate to form a substantially continuous layer. The composition includes a solvent and a solid or a solvent and a polymerizable material. The composition can be a solution or a dispersion. At least some of the solvent is evaporated from the composition, and a solid layer is formed (e.g., polymerized or dried) on the substrate. The solid layer is substantially free of interstitial voids.

Abstract: A method of patterning a substrate comprising a plurality of fields, including, inter alia, positioning a first volume of fluid on a first subset of the plurality of fields of the substrate, with the first volume of fluid being subjected to a first evaporation time; positioning a second volume of fluid on a second subset of the plurality of fields of the substrate, differing from the first subset, with the second volume of fluid being subjected to a second evaporation time, differing from the first evaporation time; and patterning the first and second subsets of the plurality of fields, with the first subset of the plurality of fields being patterned prior to the second subset of the plurality of fields being patterned, with a volume associated with the second subset of the plurality of fields being greater than a volume associated with the first subset of the plurality of fields to compensate for the second evaporation time being greater than the first evaporation time.

Abstract: Described are systems and method of using a vapor delivery system for enabling delivery of an adhesion promoter material during an imprint lithography process.

Abstract: Post sputter cleaning of hard disk substrates for use in an imprint lithography processes. The cleaning removes contaminants including organic contaminants that otherwise may cause repeating void (non-fill) defects in the imprinted pattern.

Abstract: The present invention includes a template for patterning liquids disposed on a substrate. The template includes a body having opposed first and second surfaces with one surface having at least one recess and the other surface having a patterning region. In one embodiment, the template may be mounted to a fluid chamber having an inlet and a throughway. The template may be connected to the throughway and the inlet is connected to a fluid source.

Abstract: Generating a fluid drop pattern for an imprint lithography process includes selecting an imprinting surface with features and generating a fluid drop pattern including drop locations for placement of a multiplicity of drops of substantially equal volume on an imprint lithography substrate such that some of the drops are substantially aligned with at least some of the features. The fluid drop pattern is generated through an optimization process. The fluid drop pattern allows substantially complete filling of imprinting surface features and formation of a substantially uniform residual layer during the imprint lithography process.

Abstract: A nano-imprint lithography system is described for patterning first and second substrates, the system includes a translation stage constructed to alternatively place substrate chucks in position with respect to a nano-imprint mold assembly such that the nano-imprint mold assembly may imprint a pattern on one of the substrates, while concurrently obtaining a desired spatial relationship for the remaining substrate.

Abstract: A system of patterning first and second opposed sides of a substrate is described. The system may employ a mold assembly and obtaining a desired spatial relationship between the first and second opposed sides of the substrate and the mold assembly. In a further embodiment, the method and system may employ a first and a second mold assembly.

Abstract: Densifying a multi-layer substrate includes providing a substrate with a first dielectric layer on a surface of the substrate. The first dielectric layer includes a multiplicity of pores. Water is introduced into the pores of the first dielectric layer to form a water-containing dielectric layer. A second dielectric layer is provided on the surface of the water-containing first dielectric layer. The first and second dielectric layers are annealed at temperature of 600° C. or less. In an example, the multi-layer substrate is a nanoimprint lithography template. The second dielectric layer may have a density and therefore an etch rate similar to that of thermal oxide, yet may still be porous enough to allow more rapid diffusion of helium than a thermal oxide layer.

Abstract: Detection of periodically repeating nanovoids is indicative of levels of substrate contamination and may aid in reduction of contaminants on substrates. Systems and methods for detecting nanovoids, in addition to, systems and methods for cleaning and/or maintaining cleanliness of substrates are described.

Abstract: Release agents with increased affinity toward nano-imprint lithography template surfaces interact strongly with the template during separation of the template from the solidified resist in a nano-imprint lithography process. The strong interaction between the surfactant and the template surface reduces the amount of surfactant pulled off the template surface during separation of a patterned layer from the template in an imprint lithography cycle. Maintaining more surfactant associated with the surface of the template after the separation of the patterned layer from the template may reduce the amount of surfactant needed in a liquid resist to achieve suitable release of the solidified resist from the template during an imprint lithography process. Strong association of the release agent with the surface of the template facilitates the formation of ultra-thin residual layers and dense fine features in nano-imprint lithography.

Abstract: Separation of an imprint lithography template and a patterned layer in an imprint lithography process may result in stress to features of the template and/or features of the patterned layer. Such stress may be reduced by minimizing open areas on the template, including dummy features within the open areas, and/or selective positioning of features on the template.

Abstract: The present invention is directed to a material for use in imprint lithography that features a composition having a viscosity associated therewith and including a surfactant, a polymerizable component, and an initiator responsive to a stimuli to vary the viscosity in response thereto, with the composition, in a liquid state, having the viscosity being lower than about 100 centipoises, a vapor pressure of less than about 20 Torr, and in a solid cured state a tensile modulus of greater than about 100 MPa, a break stress of greater than about 3 MPa and an elongation at break of greater than about 2%.

Abstract: The present invention is directed to a method of forming an imprinting layer on a substrate including high resolution features, and transferring the features into a solidified region of the substrate. Desired thickness of the residual layer may be minimized in addition to visco-elastic behavior of the material.

Abstract: Systems and methods for fabrication of nanostructured solar cells having arrays of nanostructures are described, including nanostructured solar cells having a repeating pattern of pyramid nanostructures, providing for low cost thin-film solar cells with improved PCE.

Abstract: Variations of interdigitated backside contact (IBC) solar cells having patterned areas formed using nano imprint lithography are described.