A pattern forming photo-curing layer is heated, thereby enabling quick shaping. A pattern manufacturing apparatus (100) includes a controller (101), a laser projector (102), and a heater (103). The controller (101) controls the laser projector (102) to form a pattern on a pattern forming sheet (130) placed on a stage (140). The laser projector (102) includes an optical engine (121), and the controller (101) controls the laser projector (102) to irradiate the pattern forming sheet (130) with a light beam from the optical engine (121). The heater (103) heats the pattern forming sheet (130).

A method of topography determination, the method including: obtaining a first focus value derived from a computational lithography model modeling patterning of an unpatterned substrate or derived from measurements of a patterned layer on an unpatterned substrate; obtaining a second focus value derived from measurement of a substrate having a topography; and determining a value of the topography from the first and second focus values.

A method for the tracking and identification of components of lithography systems, for example of projection exposure apparatuses for semiconductor lithography is provided. The components are each provided with at least one transponder. The transponder has a data memory, on which data relating to the respective component are stored. The transponder is configured to pick up wirelessly arriving signals of a reader and to respond with data from the data memory. The data are stored on the data memory during the production of the component and/or during the production of the lithography system and/or after the start-up of the lithography system.

The present invention provides a method for calibrating an encoder which includes a scale and a light receiving unit configured to receive light reflected by the scale, and detects a change in relative position between the scale and the light receiving unit, the method comprising a measurement step of measuring a deformation amount of a surface shape of the scale, a specifying step of specifying, based on a measurement result in the measurement step, a range which includes a portion of a surface of the scale, where the deformation amount exceeds a threshold, and within which a detection value of the encoder is corrected, and a determination step of determining a correction value for correcting the detection value of the encoder within the range specified in the specifying step.

The present disclosure relates a lithographic substrate marking tool. The tool includes a first electromagnetic radiation source disposed within a housing and configured to generate a first type of electromagnetic radiation. A radiation guide is configured to provide the first type of electromagnetic radiation to a photosensitive material over a substrate. A second electromagnetic radiation source is disposed within the housing and is configured to generate a second type of electromagnetic radiation that is provided to the photosensitive material.

A method including obtaining an image of a plurality of structures on a substrate, wherein each of the plurality of structures is formed onto the substrate by transferring a corresponding pattern of a design layout; obtaining, from the image, a displacement for each of the structures with respect to a reference point for that structure; and assigning each of the structures into one of a plurality of groups based on the displacement.

In some embodiments, the present disclosure relates a lithographic substrate marking tool. The lithographic substrate marking tool has a first lithographic exposure tool arranged within a shared housing and configured to generate a first type of electromagnetic radiation during a plurality of exposures. A mobile reticle has a plurality of different reticle fields respectively configured to block a portion of the first type of electromagnetic radiation to expose a substrate identification mark within a photosensitive material overlying a semiconductor substrate. A transversal element is configured to move the mobile reticle so that separate ones of the plurality of reticle fields are exposed onto the photosensitive material during separate ones of the plurality of exposures. The mobile reticle therefore allows for different strings of substrate identification marks to be formed within the photoresistive material using a same reticle, thereby economically providing the benefits of lithographic substrate marking.

The present disclosure relates a method of forming substrate identification marks. In some embodiments, the method may be performed by forming a photosensitive material over a substrate. A first type of electromagnetic radiation is selectively provided to the photosensitive material to expose a plurality of substrate identification marks within the photosensitive material, and a second type of electromagnetic radiation is selectively provided to the photosensitive material to expose one or more alignment marks within the photosensitive material. Exposed portions of the photosensitive material are removed to form a patterned photosensitive material. The substrate is etched according to the patterned photosensitive material to form recesses within the substrate that are defined by the plurality of substrate identification marks and the one or more alignment marks.

The present disclosure relates a method of forming substrate identification marks. In some embodiments, the method may be performed by forming a photosensitive material over a substrate. A first type of electromagnetic radiation is selectively provided to the photosensitive material to expose a plurality of substrate identification marks within the photosensitive material, and a second type of electromagnetic radiation is selectively provided to the photosensitive material to expose one or more alignment marks within the photosensitive material. Exposed portions of the photosensitive material are removed to form a patterned photosensitive material. The substrate is etched according to the patterned photosensitive material to form recesses within the substrate that are defined by the plurality of substrate identification marks and the one or more alignment marks.

An exposure apparatus exposes a substrate using exposure light via a liquid. The exposure apparatus comprises a substrate holding part, which releasably holds and is capable of moving a substrate, a management apparatus, which manages a status of usage of a dummy substrate that the substrate holding part is capable of holding.