A method for determining an intra-field correction for control of a lithographic apparatus configured for exposing a pattern on an exposure field of a substrate, the method includes: obtaining metrology data for use in determining the intra-field correction; determining an accuracy metric indicating a lower accuracy where the metrology data is not reliable and/or where the lithographic apparatus is limited in actuating a potential actuation input which is based on the metrology data; and determining the intra-field correction based at least partially on the accuracy metric.

A system for a semiconductor fabrication facility includes a manufacturing tool including a load port, a maintenance crane, a rectangular zone overlapping with the load port of the manufacturing tool, a plurality of first sensors at corners of the rectangular zone, an OHT vehicle, a second sensor on the OHT vehicle, a third sensor on the load port, and a control unit. The first sensors are configured to detect a location of the maintenance crane and to generate a first location data. The second sensor is configured to generate a second location data. The control unit is configured to receive the first location data of the maintenance crane and the second location data of the OHT vehicle. The control unit further sends signals to the second sensor and the third sensor or to cut off the signal to the second sensor.

Methods and apparatus for determining a subset of a plurality of relationships between a plurality of parameters describing operation of a lithographic apparatus, the method comprising: determining a first set of data describing first relationships between a plurality of parameters of a reference apparatus; based on one or more measurements, determining a second set of data describing second relationships between the plurality of parameters of the reference or a further apparatus; comparing the first set of data and the second set of data; and selecting from the second set of data a subset of the second relationships based on differences between the first set of data and the second set of data.

A method of performance testing working parameters of a fluid handing structure in an immersion lithographic apparatus, the method including: placing a test substrate having an upper surface with a first portion with a resist defining the upper surface and a second portion with a material different from the resist defining the rest of the upper surface on a table in the immersion lithographic apparatus, confining liquid on a region of an upper surface of the table and/or the upper surface of the test substrate by operating the fluid handing structure using the associated working parameters, moving the table such that the region moves from the second portion to the first portion, and detecting change to and/or residue on the first portion as a result of liquid being left behind on the first portion during the moving.

A method for controlling a manufacturing process for manufacturing semiconductor devices, the method including: obtaining performance data indicative of the performance of the manufacturing process, the performance data including values for a performance parameter across a substrate subject to the manufacturing process; and determining a process correction for the manufacturing process based on the performance data and at least one control characteristic related to a dynamic behavior of one or more control parameters of the manufacturing process, wherein the determining is further based on an expected stability of the manufacturing process when applying the process correction.

Extreme ultraviolet (EUV) lithography systems are provided. A EUV scanner is configured to perform a lithography exposure process in response to EUV radiation. A light source is configured to provide the EUV radiation to the EUV scanner. A measuring device is configured to measure concentration of debris caused by unstable target droplets in the chamber. A controller is configured to adjust a first gas flow rate and a second gas flow rate in response to the measured concentration of the debris and a control signal from the EUV scanner. A exhaust device is configured to extract the debris out of the chamber according to the first gas flow rate. A gas supply device is configured to provide a gas into the chamber according to the second gas flow rate. The control signal indicates the lithography exposure process is completed.

An extreme ultraviolet light generation apparatus may include: a chamber device including an internal space; a target supply unit disposed at the chamber device and configured to supply a droplet of a target substance to the internal space; a target collection unit disposed at the chamber device, communicated with the internal space through an opening provided to an inner wall of the chamber device, and configured to collect the droplet passing through the opening; a detection unit disposed at the chamber device and configured to detect the target substance accumulating in the vicinity of the opening of the inner wall; and a control unit configured to stop the target supply unit depending on a result of the detection by the detection unit.

According to one embodiment, a first test process concerning a light-exposure process is performed by forming a first lower layer and a first upper layer on a first substrate. A second test process concerning a light-exposure process is performed by forming a second lower layer and a second upper layer on a second substrate. A correction model is created on a basis of results obtained in the first test process and the second test process. A manufacturing process is performed by forming a third lower layer and a third upper layer on a third substrate. In the manufacturing process, an overlay estimation correction value is calculated by using the correction model, based on a first pattern position deviation amount, a step processing history in the manufacturing process, a second pattern position deviation amount, and an overlay residual, and the overlay estimation correction value is used in a light-exposure process.

A system for a semiconductor fabrication facility includes a manufacturing tool including a load port, a maintenance crane, a rectangular zone overlapping with the load port of the manufacturing tool, a plurality of first sensors at corners of the rectangular zone, an OHT vehicle, a second sensor on the OHT vehicle, a third sensor on the load port, and a control unit. The first sensors are configured to detect a location of the maintenance crane and to generate a first location data. The second sensor is configured to generate a second location data. The control unit is configured to receive the first location data of the maintenance crane and the second location data of the OHT vehicle. The control unit further sends signals to the second sensor and the third sensor or to cut off the signal to the second sensor.

Embodiments described herein provide a system, a software application, and methods of a lithography process that provide at least one of the ability to decrease the stabilization time and write an exposure pattern into a photoresist on a substrate compensating for the change in the total pitch over a stabilization time. One embodiment of the system includes a slab, a stage disposed over the slab, a pair of supports disposed on the slab, a processing apparatus, and a chiller system. The pair of supports support a pair of tracks and the stage is configured to move along the pair of tracks. The processing apparatus has an apparatus support coupled to the slab and a processing unit supported by the apparatus support. The processing unit has a plurality of image projection systems. The chiller system has at least one fluid channel disposed in each track of the pair of tracks.