Abstract: A system and method for cleaning mesa sidewalls of a template. Curable material may be deposited in a cleaning drop pattern onto a non-yielding imprint field of one of: a device yielding substrate; and a non-yielding substrate. The template may be brought into contact with the curable material. The template has: a recessed surface; a mesa extending from the recessed surface; and wherein the mesa sidewalls connect the recessed surface to the mesa. A relative position of the template to the cleaning drop pattern may be such that the curable material spreads up the mesa sidewalls and does not contact the recessed surface. Cured material may be formed by exposing the curable material to actinic radiation after the curable material has spread up the mesa sidewalls, and before the curable material contacts the recessed surface. The template may be separated from the cured material.

Abstract: Systems and methods for shaping a film by: depositing a formable material on a field of a substrate; and positioning a template relative to the field. The template has a mesa with a shaping surface and mesa sidewalls surround the shaping surface. The shaping may further comprise contacting the formable material with the shaping surface. The formable material may spread when the shaping surface is in contact with the formable material. The shaping may comprise exposing the formable material to a curing dose of actinic radiation after the formable material has spread to the edge of the field. A spatial distribution of the curing dose may be such that an interior dose applied at an interior of the field may be greater than a sidewall dose that is incident on the mesa sidewalls.

Abstract: An imprinting apparatus, a method of manufacturing an article, with a template having at least one mass velocity variation feature in a region that alters the filling rate of formable material in the second region surrounding a pattern region. The altered filling rate varies from a first filling rate, at a center of an outer edge of the region to a second filling rate, at corners of the outer edge of the region. The second filling rate is greater than the first filling rate.

Abstract: A frame curing template for imprinting formable material on a substrate and a system and a method of using the frame curing template. The template may comprise: a patterning surface on a mesa on a front side of the template; a recessed surface surrounding the mesa on the front side of the template; a recessed surface coating on the recessed surface. A first transmittance from a back side of the template through the recessed surface coating to actinic radiation may be below a first threshold transmittance. A first frame window may be inset within the recessed surface coating and surrounds the mesa. A second transmittance of the template from the back side of the template through the first frame window to the actinic radiation may be above the first threshold transmittance.

Abstract: Systems and methods for imprinting formable material on a substrate with a template. Illuminate the formable material with a gelling radiation distribution pattern. The gelling radiation distribution pattern has a gelling dosage that that varies from a minimum gelling dosage at each of a plurality of corners of a boundary edge to a peak gelling dosage at a center of each of the boundary edges.

Abstract: An imprinting template, an imprinting system, and an imprinting method for imprinting a pattern in a formable material on a substrate. The template includes an edge region that surrounds a pattern region. A full height represents an absolute value of a distance between top surface and bottom surface of the pattern region. The edge region extends to an edge of a mesa of the template. A portion of the edge region may be at least a full height below the top surface of the pattern region. An area of the portion of the edge region may be at least large enough to prevent formable material that is between the template and the substrate from extruding out beyond the edge of the mesa.

Abstract: An apparatus for imprint lithography can include a logic element configured to generate a fluid droplet pattern of fluid droplets of a formable material to be dispensed onto a substrate. The fluid droplet pattern includes an imprint field, wherein the imprint field has a side and a drop exclusion zone along the side, and the drop exclusion zone is narrower at a first point farther from the center of a side and wider at a second point closer to the center of the side. In another aspect, a method can be carried out using the apparatus. The apparatus and method can be useful in filling an imprint field with a formable material relatively quickly without extrusion defects or other complications.

Abstract: A nanoimprint lithography template, method of fabrication, and method of manufacturing an article using the same. The template includes a body having first and second opposed sides, the second side having a mesa extending therefrom, with the mesa having sidewalls and a surface. A recessed shelf extends around a perimeter of the mesa surface, with a light-blocking material positioned on at least the recessed shelf and at a thickness such that the light-blocking material does not extend beyond a plane defined by the mesa surface.

Abstract: A sacrificial-post templating method is presented for directing block copolymer (BCP) self-assembly to form nanostructures of monolayers and bilayers of microdomains. The topographical post template can be removed after directing self-assembly and, therefore, is not incorporated into the final microdomain pattern. The sacrificial posts can be a material removable using a selective etchant that will not remove the material of the final pattern block(s). The sacrificial posts may be removable, at least in part, using a same etchant as for removing one of the blocks of the BCP, for example, a negative tone polymethylmethacrylate (PMMA) when a non-final pattern block of polystyrene is removed and polydimethylsiloxane (PDMS) remains on the substrate.

Abstract: A sacrificial-post templating method is presented for directing block copolymer (BCP) self-assembly to form nanostructures of monolayers and bilayers of microdomains. The topographical post template can be removed after directing self-assembly and, therefore, is not incorporated into the final microdomain pattern. The sacrificial posts can be a material removable using a selective etchant that will not remove the material of the final pattern block(s). The sacrificial posts may be removable, at least in part, using a same etchant as for removing one of the blocks of the BCP, for example, a negative tone polymethylmethacrylate (PMMA) when a non-final pattern block of polystyrene is removed and polydimethylsiloxane (PDMS) remains on the substrate.