In a method executed in an exposure apparatus, a focus control effective region and a focus control exclusion region are set based on an exposure map and a chip area layout within an exposure area. Focus-leveling data are measured over a wafer. A photo resist layer on the wafer is exposed with an exposure light. When a chip area of a plurality of chip areas of the exposure area is located within an effective region of a wafer, the chip area is included in the focus control effective region, and when a part of or all of a chip area of the plurality of chip areas is located on or outside a periphery of the effective region of the wafer, the chip area is included in the focus control exclusion region In the exposing, a focus-leveling is controlled by using the focus-leveling data measured at the focus control effective region.

The present invention provides an imprint apparatus that forms an imprint material pattern on a substrate by using a mold, comprising: a discharge unit on which a plurality of discharge outlets configured to discharge an imprint material are arranged; a measurement unit configured to measure a relative tilt between the discharge unit and the substrate; and a control unit configured to control a process of causing the discharge unit to discharge the imprint material while relatively moving the discharge unit and the substrate to each other, wherein the control unit is configured to change a relative movement direction of the discharge unit and the substrate in the process in accordance with the relative tilt measured by the measurement unit so as to reduce an arrangement error of the imprint material, discharged from the plurality of discharge outlets, on the substrate.

According to one embodiment, a pattern forming method includes forming a resist film including a first core material pattern and a second core material pattern, on a first film laminated on a substrate; forming a second film at least on sidewalls of the first and second core material patterns; removing the first core material pattern while not removing the second core material pattern and the second film; and processing the first film by using, as a mask, the second core material pattern and the second film.

Provided herein are molecules and salts thereof, arrays containing molecules and salts thereof, solid supports containing molecules and salts thereof, kits containing molecules or salts thereof, and methods of determining alignment of photolithographic masks comprising molecules or salts thereof.

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.

The present application provides a method for improving overlay metrology accuracy of self-aligned multiple patterning, overlay metrology pattern comprising a front layer pattern and a current layer pattern, the front layer pattern comprising a plurality of first grating structures overlaid on the periphery of the current layer pattern, the first grating structure being composed of a plurality of repeatedly arranged strip elements; segmenting the strip element in the first grating structure, so that each of the strip elements forms a sub-grating structure comprising a plurality of repeatedly arranged strip structures; forming a plurality of repeatedly arranged core structures corresponding to the plurality of repeatedly arranged strip structures; form a gate structure comprising a plurality of repeatedly arranged fin structures; removing two outermost fin structures of the gate structure; the gate structure and the current layer pattern structure together forming an overlay metrology structure.

At a motherboard for an image device, which is used for manufacturing an image device such as a liquid crystal device, an organic electroluminescence device, a mirror device, and an image-capturing device, a mark for alignment is provided on an outer side of a pixel area in which a plurality of pixels are arranged. In the photo-lithography process, a light exposure mask is arranged by using the mark as a reference position. For the mark, a recessed portion provided in a motherboard main body is filled with a filling film. The recessed portion includes a first groove extending along a first direction and a second groove extending along a second direction intersecting with the first direction, the second groove not intersecting with the first groove in plan view.

A structure of a semiconductor device with a sub-segmented grating structure as a metrology mark and a method for configuring the metrology mark. The method for configuring a metrology mark may be used in a lithography process. The method may include determining an initial characteristic function of an initial metrology mark disposed within a layer stack. The method also includes perturbing one or more variables of the plurality of subsegments of the metrology mark (e.g., pitch, duty cycle, and/or line width of the plurality of subsegments) and further perturbing a thickness of one or more layers within the layer stack. The method further includes iteratively performing the perturbations until a minimized characteristic function of an initial metrology mark is determined to set a configuration for the plurality of subsegments.

According to one embodiment, a mark is a mark arranged on a substrate and including a line-and-space pattern having a substantially constant pitch on the substrate, the mark including: a first mark in which the line-and-space pattern extends in a direction at an angle that is less than 90° or greater than 90° with respect to the first direction, the first mark including a pair of first patterns arranged at a distance in a first direction along the substrate or a first periodic pattern having a period in the first direction; and a second mark in which the line-and-space pattern extends in a direction at an angle that is less than 90° or greater than 90° with respect to the second direction, the second mark including a pair of second patterns provided in correspondence with the pair of first patterns and arranged at a distance in a second direction along the substrate and intersecting the first direction or a second periodic pattern provided in correspondence with the first periodic pattern and having a period in the second direction.

A lithographic apparatus having a substrate table, a projection system, an encoder system, a measurement frame and a measurement system. The substrate table has a holding surface for holding a substrate. The projection system is for projecting an image on the substrate. The encoder system is for providing a signal representative of a position of the substrate table. The measurement system is for measuring a property of the lithographic apparatus. The holding surface is along a plane. The projection system is at a first side of the plane. The measurement frame is arranged to support at least part of the encoder system and at least part of the measurement system at a second side of the plane different from the first side.