In a method for fabricating a resist pattern, a substrate coated with a photo resist is loaded on a stage of an exposure apparatus. Underlying patterns are fabricated on the substrate. A surface slope of an exposure area on the substrate is measured. An alignment measurement is performed by detecting an alignment pattern formed in the underlying patterns. An alignment measurement result is corrected based on the measured surface slope. The substrate is aligned to a photo mask by using the corrected alignment measurement result. The photo resist is exposed to radiation passing through the photo mask to form patterns.

A system comprises a topography measurement system configured to determine a respective height for each of a plurality of locations on a substrate; and a processor configured to: determine a height map for the substrate based on the determined heights for the plurality of locations; and determine at least one alignment parameter for the substrate by comparing the height map and a reference height map, wherein the reference height map comprises or represents heights for a plurality of locations on a reference substrate portion.

An edge-dominant alignment method for use in an exposure scanner system is provided. The method includes the steps of: providing a wafer having a plurality of shot areas, wherein each shot area has a plurality of alignment marks; determining a first outer zone of the wafer, wherein the first outer zone includes a first portion of the shot areas along a first outer edge of the wafer; determining a scan path according to the shot areas of the first outer zone; and performing an aligning process to each shot area of the first outer zone according to the scan path and an alignment mark of each shot area of the first outer zone.

A position detection apparatus configured to detect a pattern including a plurality of pattern elements formed on an object includes a control unit configured to detect the pattern by performing pattern matching between a template including a plurality of feature points and the plurality of pattern elements. While, performing pattern matching, the control unit changes positions of the plurality of feature points such that a correlation between an image and the template is within a predetermined allowable range.

An alignment mark searching method is for searching an alignment mark on a base substrate, a first positioning line segment is formed in a dummy region of the base substrate, and a straight line where the first positioning line segment is positioned running through the alignment mark. The method includes: acquiring theoretical coordinates of the alignment mark; moving a detection system view field to a target position with the theoretical coordinates as a target; moving the detection system view field from the target position in a direction perpendicular to the first positioning line segment until the first positioning line segment appears in the detection system view field; and moving the detection system view field from the position of the first positioning line segment in a length direction of the first positioning line segment until the alignment mark appears in the detection system view field. The method achieves an effect that the alignment mark can be simply, conveniently and rapidly searched. A display substrate and a display apparatus are further disclosed.

A method for operating a target processing system for processing a target (23) on a chuck (13), the method comprising providing at least a first chuck position mark (27) and a second chuck position mark (28) on the chuck (13); providing an alignment sensing system (17) arranged for detecting the first and second chuck position marks (27, 28), the alignment sensing system (17) comprising at least a first alignment sensor (61) and a second alignment sensor (62); moving the chuck (13) to a first position based on at least one measurement of the alignment sensing system (17); and measuring at least one value related to the first position of the chuck.

Disclosed is a metrology apparatus and method for measuring a structure formed on a substrate by a lithographic process. The metrology apparatus comprises an illumination system operable to provide measurement radiation comprising a plurality of wavelengths; and a hyperspectral imager operable to obtain a hyperspectral representation of a measurement scene comprising the structure, or a part thereof, from scattered measurement radiation subsequent to the measurement radiation being scattered by the structure.

A method and a device for aligning two lenses, wherein the method is directed to aligning first and second optical partial systems of an optical system, which are arranged so as to be located opposite to one another. The method includes the steps of: projecting alignment marks into a first image plane of the first optical partial system, projecting the alignment marks from the first image plane onto a sensitive surface of the second optical partial system, and aligning the optical partial systems relative to one another, such that projections of the alignment marks in a depth of field of the sensitive surface are imaged at ideal positions.

A method of applying a measurement correction includes determining an orthogonal subspace used to characterize a first principal component of the measurement and a second principal component of the measurement, and rotating the orthogonal subspace by a first angle such that the first principle component rotates to become a first factor vector and the second principle component rotates to become a second factor vector. An asymmetry vector is generated by rotating the second factor vector by a second angle, where the asymmetry vector and the first factor vector define a non-orthogonal subspace. An asymmetry contribution is determined in the measurement based on the projection of the measurement onto the first factor vector in the non-orthogonal subspace. The method also includes subtracting the asymmetry contribution from the measurement.

An apparatus for measuring a position of a mark on a substrate, the apparatus comprising: an illumination system configured to condition at least one radiation beam to form a plurality of illumination spots spatially distributed in series such that during scanning of the substrate the plurality of illumination spots are incident on the mark sequentially, and a projection system configured to project radiation diffracted by the mark from the substrate, the diffracted radiation being produced by diffraction of the plurality of illumination spots by the mark; wherein the projection system is further configured to modulate the diffracted radiation and project the modulated radiation onto a detecting system configured to produce signals corresponding to each of the plurality of illumination spots, the signals being combined to determine the position of the mark.