Some implementations herein include a detection circuit and a fast and accurate in-line method for detecting blockage on a droplet generator head of an extreme ultraviolet exposure tool without impacting the flow of droplets of a target material through the droplet generator head. In some implementations described herein, the detection circuit includes a switch circuit that is configured in an open configuration, in which the switch is electrically open between two electrode elements. When an accumulation of the target material occurs across two or more electrode elements on the droplet generator head, the accumulation functions as a switch that closes the detection circuit. A controller may detect closure of the detection circuit.

The present invention provides an evaluation method for evaluating a state in an apparatus concerning particles existing inside a substrate processing apparatus for processing a substrate, including arranging a plate in a charged state inside the apparatus and obtaining the number of particles adhered to the plate by performing a dummy operation different from an operation of processing the substrate, and evaluating the state in the apparatus based on a coefficient representing a ratio of the number of particles adhered to the plate by performing the dummy operation for the plate in an uncharged state to the number of particles adhered to the plate in the charged state, and the number of particles obtained in the arranging the plate.

An immersion lithographic apparatus is provided having a substrate table including a drain configured to receive immersion fluid which leaks into a gap between an edge of a substrate on the substrate table and an edge of a recess in which the substrate is located. A thermal conditioning system is provided to thermally condition at least the portion of the recess supporting the substrate by directing one or more jets of fluid onto a reverse side of the section supporting the substrate.

A lithography system includes a collector having a mirror surface, a laser generator aiming at an excitation zone in front of the mirror surface of the collector, a droplet generator, and a droplet deflector operative to apply a force at a position between the droplet generator and the excitation zone.

An extreme ultraviolet (EUV) light concentrating apparatus including a main body having a concave inner portion and configured to rotate, a tin generator configured to generate tin drops and spray the tin drops, a tin catcher configured to process the sprayed tin drops, a protective cover configured to block the tin drops from falling into the main body, and a rotation guide configured to rotate the main body may be provided.

A control system includes a plurality of pressure sensors, each to detect a pressure in a respective dynamic gas lock (DGL) nozzle control region of a plurality of DGL nozzle control regions. Each DGL nozzle control region includes one or more DGL nozzles. The control system includes a plurality of mass flow controllers (MFCs). Each MFC of the plurality of MFCs is to control a flow velocity in a respective DGL nozzle control region of the plurality of DGL nozzle control regions. The control system includes a controller to selectively cause one or more MFCs of the plurality of MFCs to adjust flow velocities in one or more DGL nozzle control regions of the plurality of DGL nozzle control regions based on pressures detected by the plurality of pressure sensors in DGL nozzle control regions of the plurality of DGL nozzle control regions.

Some implementations described herein provide techniques and apparatuses for an extreme ultraviolet (EUV) radiation source that includes a backsplash-prevention system to reduce, minimize, and/or prevent the formation of tin (Sn) build-up in a tunnel structure of a collector flow ring that might otherwise be caused by the accumulation of Sn satellites. This reduces backsplash of Sn onto a collector of the EUV radiation source, increases the operational life of the collector (e.g., by increasing the time duration between cleaning and/or replacement of the collector), reduces downtime of the EUV radiation source, and/or enables the performance of the EUV radiation source to be sustained for longer time durations (e.g., by reducing, minimizing, and/or preventing the rate of Sn contamination of the collector), among other examples.

A method of manufacturing an integrated circuit (IC) device includes forming a photoresist layer on a substrate, and exposing the photoresist layer to light by using a photolithographic apparatus including a light generator. The light generator includes a chamber having a plasma generation space, an optical element in the chamber, and a debris shielding assembly between the optical element and the plasma generation space in the chamber, and the debris shielding assembly includes a protective film facing the optical element and being spaced apart from the optical element with a protective space therebetween, the protective space including an optical path, and a protective frame to support the protective film and to shield the protective space from the plasma generation space.

A contamination trap for use in a debris mitigation system of a radiation source, the contamination trap comprising a plurality of vanes configured to trap fuel debris emitted from a plasma formation region of the radiation source; wherein at least one vane or each vane of the plurality of vanes comprises a material comprising a thermal conductivity above 30 W m.sup.−1 K.sup.−1.

A pattering device inspection apparatus, system and method are described. According to one aspect, an inspection method is disclosed, the method including receiving, at a multi-element detector within an inspection system, radiation scattered at a surface of an object. The method further includes measuring, with processing circuitry, an output of each element of the multi-element detector, the output corresponding to the received scattered radiation. Moreover, the method includes calibrating, with the processing circuitry, the multi-element detector by identifying an active pixel area comprising one or more elements of the multi-element detector with a measured output being above a predetermined threshold. The method also includes identifying an inactive pixel area comprising a remainder of elements of the multi-element detector. Additionally, the method includes setting the active pixel area as a default alignment setting between the multi-element detector and a light source causing the scattered radiation.