Disclosed is a substrate, associated patterning device and a method for measuring a position of the substrate. The method comprises performing an alignment scan of an alignment mark to obtain simultaneously: a first measurement signal detected in a first measurement channel and a second measurement signal detected in a second measurement channel. The first and second measurement signals are processed by subtracting a first direction component of the first measurement signal from a first direction component of the second measurement signal to obtain a first processed signal, the first direction components relating to said first direction. The position of an alignment mark is determined with respect to the first direction from the first processed signal.

An exposure apparatus according to an embodiment is configured to implement an exposure process for exposing a substrate to light. The exposure apparatus includes a stage, a storage device, and a controller. The stage is configured to hold the substrate. The storage device is configured to store a plurality of correction maps each having an alignment correction value that differs from each other. The controller is configured to control in the exposure process an exposure position relative to the substrate by selecting a correction map from the correction maps based on measurement results of a plurality of alignment marks arranged on the substrate or an amount of warpage of the substrate and moving the stage based on the selected correction map.

In a beam irradiation apparatus in which a movable body holds an object, a mark detection system detects a first mark on the movable body while moving the movable body in a first direction and changing an irradiation position of a measurement beam in the first direction, the mark detection system detects a second mark while moving the movable body in the first direction and changing the irradiation position of the measurement beam in the first direction, a controller controls a position of the movable body in a second direction intersecting the first direction during a time period between the detection of the first mark and the detection of the second mark, and the controller controls the movement of the movable body to adjust a positional relation between the object on the movable body and a processing beam, based on results of the detection of the first and second marks.

An imprint lithography method for positioning substrates includes supporting first and second substrates respectively atop first and second chucks, pneumatically suspending the first and second chucks laterally within first and second bushings, supporting the first and second chucks vertically within the first and second bushings, maintaining the first and second chucks respectively in first and second fixed rotational orientations, and forcing the first and second chucks in a downward direction independently of each other respectively against first and second vertical resistive forces until first and second top surfaces of the first and second substrates are coplanar, while maintaining the first and second chucks suspended laterally within the first and second bushings and while maintaining the first and second chucks in the first and second fixed rotational orientations.

A method of determining a position of a mark including a first pattern arranged in a first layer of a substrate and a second pattern arranged in a second layer of the substrate, includes determining information concerning the position of the mark as provisional position information based on an image of the mark, acquiring relative position information indicating a relative position between the first pattern and the second pattern, and determining the position of the mark based on the provisional position information and the relative position information.

A semiconductor device capable of improving the quality of a pixel region, an electronic apparatus including the semiconductor device, and a method for manufacturing the semiconductor device are to be provided. The present technology provides a semiconductor device that includes: a first substrate in which a pixel region including a pixel having a photoelectric conversion unit is formed; and a second substrate in which a logic circuit that processes a signal output from the pixel region is formed, the first substrate and the second substrate being stacked. In the semiconductor device, at least one of marks including a mark to be used in an exposure process during the manufacture of the semiconductor device and/or a mark to be used in an inspection process for the semiconductor device is formed in a first region that is a region between a first scribe region that is a peripheral portion of the first substrate and the pixel region and/or in a second region that is a region between a second scribe region that is a peripheral portion of the second substrate and a region corresponding to the pixel region in the second substrate.

A method for calibrating the alignment of a wafer is provided. A plurality of alignment position deviation (APD) simulation results are obtained form a plurality of mark profiles. An alignment analysis is performed on a mark region of the wafer with a light beam. A measured APD of the mark region of the wafer is obtained in response to the light beam. The measured APD is compared with the APD simulation results to obtain alignment calibration data. An exposure process is performed on the wafer with a mask according to the alignment calibration data.

Disclosed is an illumination arrangement for spectrally shaping a broadband illumination beam to obtain a spectrally shaped illumination beam. The illumination arrangement comprises a beam dispersing element for dispersing the broadband illumination beam and a spatial light modulator for spatially modulating the broadband illumination beam subsequent to being dispersed. The illumination arrangement further comprises at least one of a beam expanding element for expanding said broadband illumination beam in at least one direction, located between an input of the illumination arrangement and the spatial light modulator; and a lens array, each lens of which for directing a respective wavelength band of the broadband illumination beam subsequent to being dispersed onto a respective region of the spatial light modulator.

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.

The present invention relates to an ultraviolet curable ink composition including a colorant, an epoxy monomer, an oxetane monomer, a cationic photopolymerization initiator, and a polymerization inhibitor, wherein the weight ratio of epoxy monomer:oxetane monomer is 1:0.5 to 1:6, to a method for forming a bezel pattern by using the same, to a bezel pattern manufactured thereby, and to a display substrate having the same.