An objective lens protection device, objective lens system and lithographic device. The objective lens protection device includes a main structure provided with, oppositely disposed, an air supply unit and extraction unit. The air supply unit is used to output air. The extraction unit extracts air output by the air supply unit to form at least one layer of air curtain between the air supply unit and extraction unit. The objective lens protection device can effectively control the flow rate of wind discharge, controlling wind in a laminar flow state and ensuring uniform flow field of the air curtain, and can effectively block organic matters volatilized from the bottom up, eliminate opportunity for a direct contact of the organic matters with the lens, and prevent objective lens from contamination by the volatilization of the organic matters of photoresist, thus ensuring the imaging quality of the objective lens.

A system includes optics for ultraviolet light or electrons. The optics are situated in a chamber and include a surface to control a path of photons or electrons. The system also includes a lubricated component that is distinct from the surface and is situated in the chamber. The lubricated component is lubricated with a lubricant that includes an ionic liquid having a cation and an anion, wherein at least one of the cation or the anion is organic.

The present disclosure provides an air control cabinet (ACC) module for a clean room system. The clean room system has a clean fab and a clean sub-fab. The clean fab of the clean room system is configured to be disposed with at least one wafer processing apparatus. The ACC module includes an ACC inlet tube, a main cabinet, and an ACC pipeline. The ACC inlet tube is configured to supply air from the clean fab of the clean room system to the ACC module. The main cabinet is connected to the ACC inlet tube and configured to generate clean air from the air supplied from the ACC inlet tube. The ACC pipeline is connected to the main cabinet and configured to supply the clean air generated by the main cabinet to the wafer processing apparatus in the clean fab of the clean room system.

The present invention provides a local clean microenvironment near optical surfaces of an extreme ultraviolet (EUV) optical assembly maintained in a vacuum process chamber and configured for EUV lithography, metrology, or inspection. The system includes one or more EUV optical assemblies including at least one optical element with an optical surface, a supply of cleaning gas stored remotely from the one or more optical assemblies and a gas delivery unit comprising: a plenum chamber, one or more gas delivery lines connecting the supply of gas to the plenum chamber, one or more delivery nozzles configured to direct cleaning gas from the plenum chamber to a portion of the EUV assembly, and one or more collection nozzles for removing gas from the EUV optical assembly and the vacuum process chamber.

An apparatus, which may form part of a lithographic apparatus, comprises a substrate table, a projection system, a gas lock and a gas flow guide. The substrate table is suitable for supporting a substrate. The projection system has a body which defines an interior and an opening. The projection system is configured and arranged to project a radiation beam through the opening onto a substrate supported by the substrate table. The gas lock is suitable for providing a gas flow from the opening away from the interior. The gas flow guide is configured to guide at least a portion of the gas flow away from the substrate supported by the substrate table.

A radiation source apparatus is provided. The radiation source apparatus includes a chamber, an exhaust module, a measuring device, a gas supply module and a controller. The exhaust module is configured to extract debris caused by unstable target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The gas supply module is configured to provide a gas into the chamber according to a second gas flow rate. The controller is configured to adjust the first gas flow rate and the second gas flow according to the measured concentration of the debris.

A method includes generating a plasma that emits a first EUV radiation in a vessel at a first gas exhaust rate of the vessel; directing the first EUV radiation to a first substrate using a collector in the vessel; halting the generating of the first EUV radiation; and ejecting a gas past the collector at a second gas exhaust rate of the vessel, in which the second gas exhaust rate is greater than the first gas exhaust rate after the halting.

An exposure device has a cylindrical peripheral wall member. The peripheral wall member forms a processing space in which a substrate is storable and has an upper opening and a lower opening. Further, a light emitter is provided in an upper portion of the peripheral wall member to close the upper opening. A lower lid member that is provided to be movable in an up-and-down direction and configured to be capable of closing and opening the lower opening is provided below the peripheral wall member. The atmosphere in the processing space is replaced with an inert gas with the substrate stored in the processing space and the lower opening closed by the lower lid member. In this state, vacuum ultraviolet rays are emitted to the substrate from the light emitter, and the substrate is exposed.

A method for a lithography exposing process includes placing a reticle over a reticle stage, generating a light beam by irradiating a droplet by a laser, projecting a first portion of the light beam over a plurality of light permeable protrusions formed on a reflection layer and directing, by the protrusions and the reflection layer, the first portion of the light beam to the reticle.

A one-piece clamping device, a storage system and an operating method for an EUV reticle stocker are provided. The required space for storing EUV reticles is significantly reduced while ensuring a high quality storage environment for the stored EUV reticles. A further aspect provides a stocker for storing EUV reticles.