Abstract: An optical arrangement includes an optical element (1) and a thermal manipulation device. The optical element has a substrate (2), a coating (3, 9, 5) applied to the substrate (2), and an antireflection coating (3). The coating (3, 9, 5) includes: a reflective multi-layer coating (5b) configured to reflect radiation (4) with a used wavelength (?EUV). The antireflection coating (3) is arranged between the substrate (2) and the reflective multi-layer coating (5b) to suppress reflection of heating radiation (7) with a heating wavelength (?H) that differs from the used wavelength (?EUV). The thermal manipulation device has at least one heating light source (8) to produce heating radiation (7).

Abstract: An EUV mirror with a substrate and a multilayer arrangement including: a periodic first layer group having N1>1 first layer pairs of period thickness P1 and arranged on a radiation entrance side of the multilayer arrangement; a periodic second layer group having N2>1 second layer pairs of period thickness P2 and arranged between the first layer group and the substrate; and a third layer group having N3 third layer pairs arranged between the first and second layer groups. N1>N2. The third layer group has a third period thickness P3 which deviates from an average period thickness PM=(P1+P2)/2 by a period thickness difference ?P. ?P corresponds to the quotient of the optical layer thickness (?/4) of a quarter-wave layer and the product of N3 and cos(AOIM), AOIM being the mean incidence angle for which the multilayer arrangement is designed.

Abstract: A reflective optical element (50) having a substrate (52) and a multilayer system (51) that has a plurality of partial stacks (53), each with a first layer (54) of a first material and a second layer (55) of a second material. The first material and the second material differ from one another in refractive index at an operating wavelength of the optical element. Each of the partial stacks has a thickness (Di) and a layer thickness ratio (?i), wherein the layer thickness ratio is the quotient of the thickness of the respective first layer and the partial stack thickness (Di). In a first section of the multilayer system, for at least one of the two variables of partial stack thickness (Di) and layer thickness ratio (?i), the mean square deviation from the respective mean values therefor is at least 10% less than in a second section of the multilayer system.

Abstract: An optical arrangement includes an optical element (1) and a thermal manipulation device. The optical element has a substrate (2), a coating (3, 9, 5) applied to the substrate (2), and an antireflection coating (3). The coating (3, 9, 5) includes: a reflective multi-layer coating (5b) configured to reflect radiation (4) with a used wavelength (?EUV). The antireflection coating (3) is arranged between the substrate (2) and the reflective multi-layer coating (5b) to suppress reflection of heating radiation (7) with a heating wavelength (?H) that differs from the used wavelength (?EUV). The thermal manipulation device has at least one heating light source (8) to produce heating radiation (7).

Abstract: A mirror (1a; 1a?; 1b; 1b?; 1c; 1c?) for the EUV wavelength range and having a substrate (S) and a layer arrangement, wherein the layer arrangement includes at least one surface layer system (P??) consisting of a periodic sequence of at least two periods (P3) of individual layers, wherein the periods (P3) include two individual layers composed of different materials for a high refractive index layer (H??) and a low refractive index layer (L??), wherein the layer arrangement includes at least one surface protecting layer (SPL, Lp) or at least one surface protecting layer system (SPLS) having a thickness of greater than 20 nm, and preferably greater than 50 nm.

Abstract: A reflective optical element (50) having a substrate (52) and a multilayer system (51) that has a plurality of partial stacks (53), each with a first layer (54) of a first material and a second layer (55) of a second material. The first material and the second material differ from one another in refractive index at an operating wavelength of the optical element. Each of the partial stacks has a thickness (Di) and a layer thickness ratio (?i), wherein the layer thickness ratio is the quotient of the thickness of the respective first layer and the partial stack thickness (Di). In a first section of the multilayer system, for at least one of the two variables of partial stack thickness (Di) and layer thickness ratio (?i), the mean square deviation from the respective mean values therefor is at least 10% less than in a second section of the multilayer system.

Abstract: An EUV mirror with a substrate and a multilayer arrangement including: a periodic first layer group having N1>1 first layer pairs of period thickness P1 and arranged on a radiation entrance side of the multilayer arrangement; a periodic second layer group having N2>1 second layer pairs of period thickness P2 and arranged between the first layer group and the substrate; and a third layer group having N3 third layer pairs arranged between the first and second layer groups. N1>N2. The third layer group has a mean third period thickness P3 which deviates from an average period thickness PM=(P1+P2)/2 by a period thickness difference ?P. ?P corresponds to the quotient of the optical layer thickness (?/4) of a quarter-wave layer and the product of N3 and cos(AOIM), AOIM being the mean incidence angle for which the multilayer arrangement is designed.

Abstract: An optical imaging system serving for imaging a pattern arranged in an object plane of the imaging system into an image plane of the imaging system with the aid of electromagnetic radiation from a wavelength range around a main wavelength ?0 has a multiplicity of mirrors. Each mirror has a mirror surface having a reflective layer arrangement having a sequence of individual layers.

Abstract: A mirror (1a; 1a?; 1b; 1b?; 1c; 1c?) for the EUV wavelength range and having a substrate (S) and a layer arrangement, wherein the layer arrangement includes at least one surface layer system (P??) consisting of a periodic sequence of at least two periods (P3) of individual layers, wherein the periods (P3) include two individual layers composed of different materials for a high refractive index layer (H??) and a low refractive index layer (L??), wherein the layer arrangement includes at least one surface protecting layer (SPL, Lp) or at least one surface protecting layer system (SPLS) having a thickness of greater than 20 nm, and preferably greater than 50 nm.

Abstract: An optical system of a microlithographic projection exposure apparatus permits comparatively flexible and fast influencing of the intensity distribution and/or the polarization state. The optical system includes at least one layer system that is at least one-side bounded by a lens or a mirror. The layer system is an interference layer system of several layers and has at least one liquid or gaseous layer portion with a maximum thickness of one micrometer (?m), and a manipulator for manipulation of the thickness profile of the layer portion.

Abstract: An optical imaging system serving for imaging a pattern arranged in an object plane of the imaging system into an image plane of the imaging system with the aid of electromagnetic radiation from a wavelength range around a main wavelength ?0 has a multiplicity of mirrors. Each mirror has a mirror surface having a reflective layer arrangement having a sequence of individual layers.

Abstract: EUV-mirror having a substrate (S) and a layer arrangement that includes plural layer subsystems (P?, P??) each consisting of a periodic sequence of at least two periods (P2, P3) of individual layers. The periods (P2, P3) include two individual layers composed of different materials for a high refractive index layer (H?, H??) and a low refractive index layer (L?, L??) and have within each layer subsystem (P?, P??) a constant thickness (d2, d3) that deviates from that of the periods of an adjacent layer subsystem.

Abstract: EUV mirror with a layer arrangement on a substrate. The layer arrangement includes a plurality of layer subsystems each consisting of a periodic sequence of at least one period of individual layers. The periods include two individual layers composed of different material for a high refractive index layer and a low refractive index layer and have within each subsystem a constant thickness that deviates from a period thickness of an adjacent layer subsystem. The subsystem most distant from the substrate has (i) a number of periods greater than the number of periods for the layer subsystem that is second most distant from the substrate and/or (ii) a thickness of the high refractive index layer that deviates by more than 0.1 nm from that of the high refractive index layer of the subsystem that is second most distant from the substrate.

Abstract: The disclosure concerns an optical system of a microlithographic projection exposure apparatus. To permit comparatively flexible and fast influencing of intensity distribution and/or the polarization state, an optical system includes at least one layer system that is at least one-side bounded by a lens or a mirror. The layer system is an interference layer system of several layers and has at least one liquid or gaseous layer portion with a maximum thickness of one micrometer (?m), and a manipulator for manipulation of the thickness profile of the layer portion.

Abstract: An attenuating filter provides a prescribed attenuation of the intensity of transmitted, short-wavelength, ultraviolet light, in particular, at wavelengths below 200 nm, that is governed by a predefinable spatial distribution of its spectral transmittance. The filter has a transparent substrate (3), e.g. fabricated from crystalline calcium fluoride. A filter coating (5) fabricated from a dielectric material that absorbs over a predefined wavelength range is applied to at least one surface (4) of the substrate. In the case of operating wavelengths of about 193 nm, the filter coating consists largely of tantalum pentoxide. Filters of the type, which may be inexpensively fabricated with high yields, are noted for their high abilities to withstand laser radiation and may be effectively antireflection coated employing simply designed antireflection coatings.

Abstract: An optical component and a coating system for coating substrates for optical components with essentially rotationally symmetric coatings, the system having a planetary-drive system (1) that has a rotating planet carrier (2) and several planets (4), each of which carries a single substrate, that corotate both with the planet carrier and with respect to the primary carrier. In one embodiment a set of stationary first masks (20) that allow controlling the radial variation in physical film thickness is arranged between a source (8) of material situated beneath the planets and the substrates. A set of second masks that mask off evaporation angles exceeding a limiting evaporation or incidence angle (? max) for every substrate also corotate with the primary carrier (2), which allows depositing coatings having a prescribed radial film-thickness distribution and a virtually constant density of the coating material over their full radial extents for relatively low, and only slightly varying, evaporation angles.

Abstract: Antireflection multilayer coatings with only three or four layers are proposed for the production of laser resistant optical components with minimal residual reflection and high transparency for UV light in a wavelength range approx. 150 nm to approx. 250 nm at large angles of incidence in the range of approx. 70° to approx. 80°, particularly in the range between approx. 72° and approx. 76°. For incident p-polarized UV light three-layer systems can be used, in which a layer of low refractive material, in particular magnesium fluoride is arranged between two layers of high refractive material and, in the case of the specified wavelength, of minimally absorbent material, in particular of hafnium oxide or aluminum oxide. For example, this allows a residual reflection of perceptibly less than 1% to be achieved in the case of a wavelength of 248 nm at angles of incidence in the range between approx. 72° and approx. 76°.

Abstract: Antireflection multilayer coatings with only three or four layers are proposed for the production of laser resistant optical components with minimal residual reflection and high transparency for UV light in a wavelength range approx. 150 nm to approx. 250 nm at large angles of incidence in the range of approx. 70° to approx. 80°, particularly in the range between approx. 72° and approx. 76°. For incident p-polarized UV light three-layer systems can be used, in which a layer of low refractive material, in particular magnesium fluoride is arranged between two layers of high refractive material and, in the case of the specified wavelength, of minimally absorbent material, in particular of hafnium oxide or aluminum oxide. For example, this allows a residual reflection of perceptibly less than 1% to be achieved in the case of a wavelength of 248 nm at angles of incidence in the range between approx. 72° and approx. 76°.

Abstract: An attenuating filter provides a prescribed attenuation of the intensity of transmitted, short-wavelength, ultraviolet light, in particular, at wavelengths below 200 nm, that is governed by a predefinable spatial distribution of its spectral transmittance. The filter has a transparent substrate (3), e.g. fabricated from crystalline calcium fluoride. A filter coating (5) fabricated from a dielectric material that absorbs over a predefined wavelength range is applied to at least one surface (4) of the substrate. In the case of operating wavelengths of about 193 nm, the filter coating consists largely of tantalum pentoxide. Filters of the type, which may be inexpensively fabricated with high yields, are noted for their high abilities to withstand laser radiation and may be effectively antireflection coated employing simply designed antireflection coatings.

Abstract: An optical component and a coating system for coating substrates for optical components with essentially rotationally symmetric coatings, the system having a planetary-drive system (1) that has a rotating planet carrier (2) and several planets (4), each of which carries a single substrate, that corotate both with the planet carrier and with respect to the primary carrier. In one embodiment a set of stationary first masks (20) that allow controlling the radial variation in physical film thickness is arranged between a source (8) of material situated beneath the planets and the substrates. A set of second masks that mask off evaporation angles exceeding a limiting evaporation or incidence angle (? max) for every substrate also corotate with the primary carrier (2), which allows depositing coatings having a prescribed radial film-thickness distribution and a virtually constant density of the coating material over their full radial extents for relatively low, and only slightly varying, evaporation angles.