An apparatus and method for irradiating a fluid containing a material to be irradiated, comprising at least one irradiation chamber having at least one inlet port and outlet port, at least one fluid cooling chamber having at least one inlet port and outlet port, one or more UV radiation sources coupled to the irradiation chamber(s); and at least one heat exchange mechanism thermally coupled to the radiation source(s) and the cooling chamber(s). At least a portion of the interior surface of the cooling chamber(s) may comprise at least a portion of the exterior surface of the irradiation chamber(s) so the cooling chamber(s) is in fluid communication with the irradiation chamber(s).

The disclosure provides a method that includes filling a cavity in a substrate with a second material, wherein the substrate includes a first material. The method also includes using galvanic and/or chemical deposition of a third material to apply an overcoating to a first surface of the substrate in a region of the cavity. The method further includes removing the second material from the cavity. In addition, the method includes, before or after removing the second material from the cavity, applying a reflective layer to the overcoating. The disclosure also provides related optical articles and systems.

A radioisotope production apparatus comprising an electron source arranged to provide an electron beam. The electron source comprises an electron injector and an electron accelerator. The radioisotope production apparatus further comprises a target support structure configured to hold a target and a beam splitter arranged to direct the a first portion of the electron beam along a first path towards a first side of the target and to direct a second portion of the electron beam along a second path towards a second side of the target.

The disclosure provides a method that includes filling a cavity in a substrate with a second material, wherein the substrate includes a first material. The method also includes using galvanic and/or chemical deposition of a third material to apply an overcoating to a first surface of the substrate in a region of the cavity. The method further includes removing the second material from the cavity. In addition, the method includes, before or after removing the second material from the cavity, applying a reflective layer to the overcoating. The disclosure also provides related optical articles and systems.

A radioisotope production apparatus (RI) comprising an electron source arranged to provide an electron beam (E). The electron source comprises an electron injector (10) and an electron accelerator (20). The radioisotope production apparatus (RI) further comprises a target support structure configured to hold a target (30) and a beam splitter (40) arranged to direct the a first portion of the electron beam along a first path towards a first side of the target (30) and to direct a second portion of the electron beam along a second path towards a second side of the target (30).

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.

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 apparatus and method for irradiating a fluid containing a material to be irradiated, comprising at least one irradiation chamber having at least one inlet port and outlet port, at least one fluid cooling chamber having at least one inlet port and outlet port, one or more UV radiation sources coupled to the irradiation chamber(s); and at least one heat exchange mechanism thermally coupled to the radiation source(s) and the cooling chamber(s). At least a portion of the interior surface of the cooling chamber(s) may comprise at least a portion of the exterior surface of the irradiation chamber(s) so the cooling chamber(s) is in fluid communication with the irradiation chamber(s).

An apparatus and method for irradiating a fluid containing a material to be irradiated, comprising at least one irradiation chamber having at least one inlet port and outlet port, at least one fluid cooling chamber having at least one inlet port and outlet port, one or more UV radiation sources coupled to the irradiation chamber(s); and at least one heat exchange mechanism thermally coupled to the radiation source(s) and the cooling chamber(s). At least a portion of the interior surface of the cooling chamber(s) may comprise at least a portion of the exterior surface of the irradiation chamber(s) so the cooling chamber(s) is in fluid communication with the irradiation chamber(s).

A mirror, in particular for a microlithographic projection exposure apparatus, has an optical effective surface and includes a substrate (11, 61, 71, 81, 91), a reflection layer system (16, 66, 76, 86, 96) for reflecting electromagnetic radiation impinging on the optical effective surface (10a, 60a, 70a, 80a, 90a), an electrode arrangement (13, 63, 73, 83) composed of a first material having a first electrical conductivity, the electrode arrangement being provided on the substrate, and a mediator layer (12, 62, 72, 82, 92) composed of a second material having a second electrical conductivity. The ratio between the first electrical conductivity and the second electrical conductivity is at least 100. The mirror also includes at least one compensation layer (88) which at least partly compensates for the influence of a thermal expansion of the electrode arrangement (83) on the deformation of the optical effective surface (80a).