In accordance with some embodiments, a lithography method in semiconductor manufacturing is provided. The lithography method includes transmitting a main pulse laser to a zone of excitation through a first optic assembly. The lithography method further includes supplying a coolant to the first optic assembly and detecting a temperature of the coolant with a use of at least one sensor. The lithography method also includes adjusting a heat transfer rate between the coolant and the first optic assembly based on the temperature of the first optic assembly. In addition, the lithography method includes generating a droplet of a target material into the zone of excitation. The lithography method further includes exciting the droplet of the target material into plasma with the main pulse laser in the zone of excitation.

An optical diffraction component is configured to suppress at least one target wavelength by destructive interference. The optical diffraction component includes at least three diffraction structure levels that are assignable to at least two diffraction structure groups. A first of the diffraction structure groups is configured to suppress a first target wavelength λ.sub.1. A second of the diffraction structure groups is configured to suppress a second target wavelength λ.sub.2, where (λ.sub.1−λ.sub.2).sup.2/(λ.sub.1+λ.sub.2).sup.2<20%. A topography of the diffraction structure levels can be described as a superimposition of two binary diffraction structure groups. Boundary regions between adjacent surface sections of each of the binary diffraction structure groups have a linear course and are superimposed on one another at most along sections of the linear course.

Some embodiment describe a reflector comprising a hollow body having an interior surface defining a passage. The interior surface has an optical surface part configured to reflect radiation and a supporter surface part. The optical surface part has a predetermined optical power and the supporter surface part does not. The reflector can be made by providing an axially symmetric mandrel, shaping a part of the circumferential surface of the mandrel to form an inverse optical surface part that is not rotationally symmetric about the axis of the mandrel, forming a reflector body around the mandrel and releasing the reflector body from the mandrel whereby the reflector body has an optical surface defined by the inverse optical surface part and a supporter surface part defined by the rest of the outer surface of the mandrel.

An extreme ultraviolet chamber apparatus includes: a chamber; an EUV condensing mirror arranged in the chamber; a first nozzle arranged in an outer peripheral portion of the EUV condensing mirror and configured to feed a gas in a first direction along a reflective surface of the EUV condensing mirror; a second nozzle arranged in the outer peripheral portion of the EUV condensing mirror and configured to feed a gas in a second direction away from the EUV condensing mirror; and an exhaust port arranged in the chamber.

A mirror for an illumination optical unit of a projection exposure apparatus comprises a spectral filter in the form of a grating structure, wherein the grating structure has a maximum edge steepness in the range of 15° to 60°.

A single-shot metrology for direct inspection of an entirety of the interior of an EUV vessel is provided. An EUV vessel including an inspection tool integrated with the EUV vessel is provided. During an inspection process, the inspection tool is moved into a primary focus region of the EUV vessel. While the inspection tool is disposed at the primary focus region and while providing a substantially uniform and constant light level to an interior of the EUV vessel by way of an illuminator, a panoramic image of an interior of the EUV vessel is captured by way of a single-shot of the inspection tool. Thereafter, a level of tin contamination on a plurality of components of the EUV vessel is quantified based on the panoramic image of the interior of the EUV vessel. The quantified level of contamination is compared to a KPI, and an OCAP may be implemented.

An extreme ultraviolet (EUV) lithography system includes a vane bucket module. The vane bucket module includes a collecting tank and a temperature adjusting pack. The collecting tank has a cover and the cover includes a plurality of through holes. Thicknesses of edges of the cover is greater than a thickness of a center of the cover. The temperature adjusting pack surrounds the collecting tank. The temperature adjusting pack includes a plurality of inlets aligned with the through holes.

An extreme ultraviolet light generation device configured to generate extreme ultraviolet light by irradiating a target containing tin with a pulse laser beam includes a chamber container, a hydrogen gas supply unit configured to supply hydrogen gas into the chamber container, a heat shield disposed between the chamber container and a predetermined region in which the target is irradiated with the pulse laser beam inside the chamber container, a first cooling medium flow path disposed in the chamber container, a second cooling medium flow path disposed in the heat shield, and a cooling device configured to supply a first cooling medium to the first cooling medium flow path and supply a second cooling medium to the second cooling medium flow path so that a temperature of the heat shield becomes lower than a temperature of the chamber container.

An extreme ultraviolet light generation apparatus includes: an optical base; and a chamber module replaceable from the optical base. The chamber module includes a chamber in which extreme ultraviolet light is generated, a condenser mirror disposed inside the chamber and configured to condense extreme ultraviolet light generated inside the chamber, a window configured to transmit, into the chamber, a laser beam introduced into the optical base, and having a function to seal up the chamber, and a laser beam condensation optical system configured to condense the laser beam having transmitted through the window.

A system and method of removing target material debris deposits simultaneously with generating EUV light includes generating hydrogen radicals in situ in the EUV vessel, proximate to the target material debris deposits and volatilizing the target material debris deposits and purging the volatilized target material debris deposits from the EUV vessel without the need of an oxygen containing species in the EUV vessel.