In a method of inspecting an outer surface of a mask pod, a stream of air is directed at a first location of a plurality of locations on the outer surface. One or more particles are removed by the directed stream of air from the first location on the outer surface. Scattered air from the first location of the outer surface is extracted and a number of particles in the extracted scattered air is determined as a sampled number of particles at the first location. The mask pod is moved and the stream of air is directed at other locations of the plurality of locations to determine the sampled number of particles in extracted scattered air at the other locations. A map of the particles on the outer surface of the mask pod is generated based on the sampled number of particles at the plurality of locations.

A debris collection and metrology system for collecting and analyzing debris from a tip used in nanomachining processes, the system including an irradiation source, an irradiation detector, an actuator, and a controller. The irradiation source is operable to direct incident irradiation onto the tip, and the irradiation detector is operable to receive a sample irradiation from the tip, the sample irradiation being generated as a result of the direct incident irradiation being applied onto the tip. The controller is operatively coupled to an actuator system and the irradiation detector, and the controller is operable to receive a first signal based on a first response of the irradiation detector to the sample irradiation, and the controller is operable to effect relative motion between the tip and at least one of the irradiation source and the irradiation detector based on the first signal.

A method is described. The method includes obtaining a relationship between a thickness of a contamination layer formed on a mask and an amount of compensation energy to remove the contamination layer, obtaining a first thickness of a first contamination layer formed on the mask from a thickness measuring device, and applying first compensation energy calculated from the relationship to a light directed to the mask.

A method for operating an EUV lithography apparatus (1) with at least one vacuum housing (27) for at least one reflective optical element (12) includes operating the EUV lithography apparatus in an exposure operating mode (B), in which EUV radiation (5) is radiated into the vacuum housing, wherein a reducing plasma is generated at a surface (12a) of the reflective optical element in response to an interaction of the EUV radiation with a residual gas present in the vacuum housing. After an exposure pause, in which no EUV radiation is radiated into the vacuum housing, and before renewed operation of the EUV lithography apparatus in the exposure operating mode (B), the EUV lithography apparatus is operated in a recovery operating mode, in which oxidized contaminants at the surface of the reflective optical element are reduced in order to recover a transmission of the EUV lithography apparatus before the exposure pause.

A cleaning apparatus for cleaning a substrate includes a lamp for emitting ultraviolet radiation in an irradiation region; a housing that houses the lamp; a water deflector spaced below the housing, the water deflector having a water inlet for receiving a supply of ozonated water and a water outlet for discharging ozonated water irradiated by the lamp into a substrate processing region beneath the water deflector, and defining a water flow path between the water inlet and the water outlet, the water flow path extending in the irradiation region; an upper reflector extending along and above the lamp; and a lower reflector extending along and below the water deflector, wherein the upper reflector and the lower reflector at least partially define the irradiation region and reflect ultraviolet radiation toward the water flow path, and wherein the lower reflector shields the substrate from ultraviolet radiation emitted by the lamp.

A vessel (16) for an EUV radiation source, the vessel comprising a first opening (30) for accessing an interior (32) of the vessel, a first access member (34) configured to allow or prevent access to the interior of the vessel through the first opening, a second opening (36) for accessing the interior of the vessel, the second opening being arranged in the first access member and a second access member (38) arranged on the first access member and configured to allow or prevent access to the interior of the vessel through the second opening.

A method for drying a component interior of a component can be used in a lithographic process chain. The method includes a first drying step, in which simultaneously heated air is admitted into a component interior through an inlet, and the heated air is sucked out of the component interior through an outlet. The method also includes a succeeding second drying step, in which the inlet for the heated air is closed and the air is sucked out of the component interior, resulting in a reduced pressure is generated in the component interior.

A cleaning machine and a cleaning method for a photomask pellicle are provided. The cleaning machine at least includes: an air knife and a cleaning device. The air knife is configured to blow away contamination particles on the surface of the photomask pellicle. The cleaning device is configured to spray cleaning liquid to the surface of the photomask pellicle, to weather the contamination particles failed to be blown away by the air knife through the volatilization of the cleaning liquid. The air knife is also configured to blow away the weathered contamination particles.

An photolithographic apparatus includes a particle removing cassette selectively extendable from the processing apparatus. The particle removing cassette includes a wind blade slit and an exhausting slit. The wind blade slit is configured to direct pressurized cleaning material to a surface of the mask to remove the debris particles from the surface of the mask. The exhausting slit collects the debris particles separated from the surface of the mask and contaminants through the exhaust line. In some embodiments, the wind blade slit includes an array of wind blade nozzles spaced apart within the wind blade slit. In some embodiments, the exhausting slit includes array of exhaust lines spaced apart within the exhausting slit.

A collector mirror for an extreme ultraviolet (EUV) light generator includes a first mirror in a vessel, the vessel being configured to receive a material and a laser beam for generating the EUV light, a second mirror surrounding the first mirror, and a detachable third mirror between the first mirror and the second mirror, the third mirror having an inner diameter that is not smaller than an outer diameter of the first mirror, and an outer diameter that is not larger than an inner diameter of the second mirror.