Provided are: a frame-shaped pellicle frame 1 having a pellicle frame main body 1a and an insulation layer 1b covering the pellicle frame main body; a pellicle comprising a pellicle film that is provided on the pellicle frame 1 and a top end surface 13 of the pellicle frame with an adhesive or pressure-sensitive adhesive therebetween; a pellicle-equipped exposure original plate; an exposure method; a method for manufacturing a semiconductor; and a method for manufacturing a liquid crystal display board. The pellicle frame can reduce falling of a foreign matter adhered to the surface thereof.

An extreme ultraviolet light (EUV) source apparatus includes a light source part for generating a plasma that emits EUV light; a first vacuum housing in which the light source part is located; a second vacuum housing arranged between the first vacuum housing and a utilizing apparatus in which the EUV light is utilized; and a debris trap located inside the second vacuum housing for deflecting debris particles emitted from the plasma, whereby the debris particles do not ingress into the utilizing apparatus. Between the first and second vacuum housings, there is provided a window through which the EUV light emitted from the light source part passes from the first vacuum housing to the second vacuum housing. A wall of the second vacuum housing has a through-hole and a window that is configured to allow the EUV light to pass from the second vacuum housing to the utilizing apparatus.

An extreme ultra violet (EUV) light source apparatus includes a metal droplet generator, a collector mirror, an excitation laser inlet port for receiving an excitation laser, a first mirror configured to reflect the excitation laser that passes through a zone of excitation, and a second mirror configured to reflect the excitation laser reflected by the first mirror.

A lithography system includes a radiation source configured to generate a radiation, a reticle configured to redirect the radiation, a first type injection nozzle proximal to the reticle and configured to generate a first particle shield in a propagation path of the radiation, and a second type injection nozzle proximal to the radiation source and configured to generate a second particle shield in the propagation path of the radiation. The second type injection nozzle and the first type injection nozzle are of different types.

A stocker for holding a plurality of reticle pods is provided. Each of the reticle pods is configured to accommodate a reticle assembly. The reticle assembly includes a reticle and a pellicle covering the reticle. The stocker includes a main frame and an electrostatic generator. The main frame has an inner space and at least one pod support disposed in the inner space. The pod support divides the inner space into a plurality of chambers configured to respectively accommodate the plurality of reticle pods. The electrostatic generator is coupled to the reticle assembly and configured to generate static electricity to the reticle assembly. The static electricity alternates between positive electricity and negative electricity.

An extreme ultraviolet (EUV) photolithography system detects debris travelling from an EUV generation chamber to a scanner. The photolithography system includes a detection light source and a sensor. The detection light source outputs a detection light across a path of travel of debris particles from the EUV generation chamber. The sensor senses debris particles by detecting interaction of the debris particles with the detection light.

Particulate deposition rate on a photolithographic mask, particularly of tin (Sn) particles produced within an EUV light source, is reduced by producing turbulence within a radiation source chamber of the EUV light source. Turbulence can be produced by changing the temperature, pressure, and/or gas flow rate within the radiation source chamber. The turbulence reduces the number of particles exiting the EUV light source which could be deposited on the photomask.

An extreme ultraviolet (EUV) source includes a collector associated with the vessel. The extreme ultraviolet (EUV) source includes a plurality of vanes along walls of the vessel. Each vane includes a stacked vane segment, and the stacked vane segments for each vane are stacked in a direction of drainage of tin (Sn) in the vessel. The EUV source includes a thermal control system comprising a plurality of independently controllable heating elements, where a heating element is configured to provide localized control for heating of a vane segment of the stacked vane segments.

A coating is included on one or more components of a lithography system. The coating reduces surface roughness of the one or more surfaces, increases flatness of the one or more surfaces, and/or increases uniformity of the one or more surfaces. The coating may be formed on the one or more surfaces using one or more of the techniques described herein. The coating is configured to reduce adhesion of target material particles to the one or more surfaces, is configured to resist buildup of target material particles on the one or more surfaces, is configured to provide resistance against oxidation of the one or more surfaces, is configured to resist thermal damage of the one or more surfaces, and/or is configured to enable the lithography system to operate at higher operating temperatures, among other examples.

An apparatus for reducing hydrogen permeation of a mask is provided when generating extreme ultraviolet (EUV) radiation. The apparatus includes a mask stage configured to hold the mask, a hydrogen dispensing nozzle configured to eject hydrogen below the mask, and a trajectory correcting assembly. The trajectory correcting assembly includes a correcting nozzle and a gas flow detector. The correcting nozzle is configured to dispense at least one flow adjusting gas to adjust a trajectory of the hydrogen away from the mask to reduce hydrogen permeation at an edge of the mask. The gas flow detector is configured to measure a variation of an airflow of the hydrogen adjusted by the at least one flow adjusting gas.