Abstract: In order to reduce the adverse influence of contamination composed of silicon dioxide, hydrocarbons and/or metals within an EUV lithography apparatus on the reflectivity, a reflective optical element (50) for the extreme ultraviolet wavelength range having a reflective surface (59) is proposed, wherein the multilayer coating of the reflective surface (59) has a topmost layer (56) composed of a fluoride. The contaminations mentioned, which deposit on the reflective optical element (50) during the operation of the EUV lithography apparatus, are converted into volatile compounds by the addition of at least one of the substances mentioned hereinafter: atomic hydrogen, molecular hydrogen, perfluorinated alkanes such as e.g. tetrafluoromethane, oxygen, nitrogen and/or helium.

Abstract: A method and an optical arrangement for removing contamination on optical surfaces (26), which are arranged in a vacuum environment in an optical arrangement, preferably in a projection exposure apparatus (1) for EUV lithography. The method includes generating a residual gas atmosphere containing molecular hydrogen (18) and at least one inert gas (17) in the vacuum environment, generating inert gas ions (21) by ionization of the inert gas (17), preferably with EUV radiation (20), and generating atomic hydrogen (27) by acceleration of the inert gas ions (21) in the residual gas atmosphere, to remove the contamination.

Abstract: An optical arrangement, in particular in a projection exposure apparatus for EUV lithography. In an aspect an optical arrangement has a housing (100, 200, 550, 780) in which at least one optical element is arranged, and at least one subhousing (140, 240, 560, 790, 811, 823, 824, 831, 841) which is arranged within the housing and which surrounds at least one beam incident on the optical element in operation of the optical system, wherein the internal space of the subhousing is in communication with the external space of the subhousing by way of at least one opening, wherein provided in the region of the opening is at least one flow guide portion which deflects a flushing gas flow passing through the opening from the internal space to the external space of the subhousing, at least once in its direction.

Abstract: In order to limit the negative effect of metal contamination on reflectivity within an EUV lithography device, a reflective optical element is proposed for the extreme ultraviolet and soft X-ray wavelength range with a reflective surface with an uppermost layer, in which the uppermost layer comprises one or more organic silicon compounds with a carbon-silicon and/or silicon-oxygen bond.

Abstract: A method for preventing contaminating gaseous substances (18) from passing through an opening (17b) in a housing (4a) of an EUV lithography apparatus (1), wherein at least one optical element for guiding EUV radiation (6) is arranged in the housing (4a). The method involves: generating at least one gas flow (21a, 21b) which deflects the contaminating substances (18, 18?), and in particular is directed counter to the flow direction (Z) thereof, in the region of the opening (17b). The gas flow (21a, 21b) and the EUV radiation (6) are generated in pulsed fashion and the pulse rate of the gas flow (21a, 21b) is defined in a manner dependent on the pulse rate of the contaminating substances (18, 18?) released under the action of the pulsed EUV radiation (6), wherein both pulse rates are preferably equal in magnitude, and wherein, in the region of the opening (17b), the gas pulses temporally overlap the pulses of the contaminating substances (18, 18?).

Abstract: An EUV lithography device including an illumination device for illuminating a mask at an illumination position in the EUV lithography device and a projection device for imaging a structure provided on the mask onto a light-sensitive substrate. The EUV lithography device has a processing device (15) for processing an optical element (6a), in particular the mask, preferably in a locally resolved manner, at a processing position in the EUV lithography device. For activating at least one gas component of the gas stream (27), the processing device (15) comprises a particle generator (30) for generating a particle beam, in particular an electron beam (30a), and/or a high-frequency generator.

Abstract: The invention relates to an EUV lithography apparatus with at least one EUV-reflective optical surface and a cavity ringdown reflectometer adapted to determine the contamination status of the EUV-reflective optical surface for at least one contaminating substance by determining the reflectivity of the EUV-reflective optical surface for radiation at a measuring wavelength (?m). The invention further relates to a method for determining the contamination status of at least one EUV-reflective optical surface arranged in an EUV lithography apparatus for at least one contaminating substance comprising determining the reflectivity of the EUV-reflective optical surface for radiation at a measuring wavelength (?m) using a cavity ringdown reflectometer.

Abstract: In EUV lithography apparatuses (10), it is proposed, in order to lengthen the lifetime of contamination-sensitive components, to arrange them in a protection module. The protection module comprises a housing (23-29) having at least one opening (37-47), in which at least one component (13a, 13b, 15, 16, 18, 19) is arranged and at which one or more gas feeds (30-36) are provided in order to introduce a gas flow into the housing (23-29), which emerges through the at least one opening (37-47). In order to effectively prevent contaminating substances from penetrating into the protection module, a light source (48-56) is arranged at the at least one opening (37-47), which light source illuminates the opening (37-47) with one or more wavelengths by which the contaminating substances can be dissociated before they penetrate through the opening (37-47).

Abstract: An EUV (extreme ultraviolet) lithography apparatus (1) including: a housing (1a) enclosing an interior (15), at least one reflective optical element (5, 6, 8, 9, 10, 14.1 to 14.6) arranged in the interior (15), a vacuum generating unit (1b) generating a residual gas atmosphere in the interior (15), and a residual gas analyzer (18a, 18b) detecting at least one contaminating substance (17a) in the residual gas atmosphere. The residual gas analyzer (18a) has a storage device (21) having an ion trap for storing the contaminating substance (17a). Additionally, a method for detecting at least one contaminating substance by residual gas analysis of a residual gas atmosphere of an EUV lithography apparatus (1) having a housing (1a) having an interior (15), in which at least one reflective optical element (5, 6, 8, 9, 10, 14.1 to 14.6), is arranged, wherein the contaminating substance (17a) is stored in a storage device (21) in order to carry out the residual gas analysis.

Abstract: An optical assembly is mounted in a projection exposure apparatus (101) for EUV microlithography and includes at least one vacuum chamber (70, 71, 68a), at least one optical element (6, 7; 65, 66; 63) arranged in the vacuum chamber (70, 71, 68a), the optical element (6, 7; 65, 66; 63) having an optical surface (18) arranged to be impinged upon by a useful beam bundle (3) of the projection exposure apparatus (101), and a cleaning device (72) configured to clean the optical surface (18). The cleaning device (72) is configured to perform particle cleaning of the optical surface (18) at a gas pressure within the vacuum chamber (70,71, 68a) which is higher than a vacuum pressure (po) for performing an exposure operation with the projection exposure apparatus (101). As a result, optical elements having respective optical surfaces arranged to be impinged upon by a useful beam bundle can be cleaned reliably of foreign particles.

Abstract: An optical arrangement, in particular a projection system, illumination system or beam shaping system for EUV lithography, including at least one optical element that is arranged in a beam path of the optical arrangement and that reflects radiation in the soft X-ray- or EUV wavelength range, wherein at least during operation of the optical arrangement at least one of, preferably each of, the reflective optical elements in the beam path, at least at the optical surface, has an operating temperature of approximately 30° C. or more, preferably of approximately 100° C. or more, particularly preferably of approximately 150° C. or more, and even more preferably of approximately 250° C. or more, and wherein the optical design of the at least one reflective optical element is selected such that its optical characteristics are optimised for operation at the operating temperature. Also presented is a method for providing a reflective optical element with such an optical design.

Abstract: One embodiment of the present invention provides a polyamide powder, which includes polyamide particles having a median grain size d 50 of from 20 to 90 ?m, a content of fines <5 ?m of below 1% by weight, and at least 75% by weight of spherical particles in which all three spatial axes x, y and z of the individual particles have the same dimensions to within ±10%. Other embodiments of the invention provide a process for making and using the powder, and articles coated articles obtained thereby.

Abstract: A method of improving perspiration absorbency in a shoe or boot using particulate amorphous silica as an absorbent in insoles for shoes and/or boots, as well as a shoe insole containing an absorbent which contains particulate amorphous silica, and footware containing the insole.

Abstract: Components (30) in the interior of an EUV lithography device for extreme ultraviolet and soft X-ray wavelength range are cleaned by igniting a plasma, adjacent to the component (30) to be cleaned, using electrodes (29), wherein the electrodes (29) are adapted to the form of the component (30) to be cleaned. The residual gas atmosphere is measured spectroscopically on the basis of the plasma. An emission spectrum is preferably recorded in order to monitor the degree of cleaning. An optical fiber cable (31) with a coupling-in optical unit (32) is advantageously used for this purpose. Moreover, in order to monitor the contamination in the gas phase within the vacuum chambers during the operation of an EUV lithography device, it is proposed to provide modules configured to initiate a gas discharge and to detect radiation emitted on account of the gas discharge. The contamination in the gas phase can be deduced from the analysis of the measured spectrum.

Abstract: A cleaning module for an EUV lithography device with a supply (206) for molecular hydrogen, a heating filament (210) and a line (212) for atomic and/or molecular hydrogen. The line (212) has at least one bend with a bending angle of less than 120 degrees, and has a material on its inner surface which has a low recombination rate for atomic hydrogen. The supply (206) is of flared shape at its end, which faces the heating filament (210). A gentler cleaning of optical elements is achieved with such a cleaning module, or also by exciting a cleaning gas with a cold cathode or a plasma, or by filtering out charged particles via of electrical and/or magnetic fields.

Abstract: In order to clean optical components (35) inside an EUV lithography device in a gentle manner, a cleaning module for an EUV lithography device includes a supply line for molecular hydrogen and a heating filament for producing atomic hydrogen and hydrogen ions for cleaning purposes. The cleaning module also has an element, (33) arranged to apply an electric and/or magnetic field, downstream of the heating filament (29) in the direction of flow of the hydrogen (31, 32). The element can be designed as a deflection unit, as a filter unit and/or as an acceleration unit for the ion beam (32).

Abstract: A lithographic apparatus includes a projection system constructed and arranged to project a beam of radiation onto a target portion of a substrate, an internal sensor having a sensing surface, and a mini-reactor movable with respect to the sensor. The mini-reactor includes an inlet for a hydrogen containing gas, a hydrogen radical generator, and an outlet for a hydrogen radical containing gas. The mini-reactor is constructed and arranged to create a local mini-environment comprising hydrogen radicals to treat the sensing surface.

Abstract: The invention is directed to a method for at least partially removing a contamination layer (15) from an optical surface (14a) of an EUV-reflective optical element (14) by bringing a cleaning gas into contact with the contamination layer. In the method, a jet (20) of cleaning gas is directed to the contamination layer (15) for removing material from the contamination layer (15). The contamination layer (15) is monitored for generating a signal indicative of the thickness of the contamination layer (15) and the jet (20) of cleaning gas is controlled by moving the jet (20) of cleaning gas relative to the optical surface (14a) using this signal as a feedback signal. A cleaning arrangement (19 to 24) for carrying out the method is also disclosed. The invention also relates to a method for generating a jet (20) of cleaning gas and to a corresponding cleaning gas generation arrangement.

Abstract: A mirror serves for guiding a radiation bundle. The mirror has a basic body and a coating of a reflective surface of the basic body, the coating increasing the reflectivity of the mirror. A heat dissipating device serves for dissipating heat deposited in the coating. The heat dissipating device has at least one Peltier element. The coating is applied directly on the Peltier element. A temperature setting apparatus has at least one temperature sensor for a temperature of the reflective surface. A regulating device of the Temperature setting apparatus can be connected to the at least one Peltier element and is signal-connected to the at least one temperature sensor. The result is a mirror in which a heat dissipating capacity of the heat dissipating device is improved.

Abstract: An optical element includes first regions which reflect or transmit the light falling on the optical element. The optical element also includes second regions which are in each instance separated by a distance from a first region and which at least partially surround a first region. The second regions are designed to be at least in part electrically conductive and are electrically insulated from the first regions. The optical element includes a carrier element and at least two first regions in the form of mirror facets which are arranged on the carrier element. The second regions are arranged with a separation from the mirror facets on the carrier element and are electrically insulated against the carrier element as well as against the mirror facet. At least one mirror facet is surrounded by an electrically conductive second region.