Abstract: The present invention relates to a holographic storage medium (10) comprising a recording medium (12) sandwiched between a substrate layer (14) and a super-strate layer (16), and a regular spacer arrangement (18) provided in the recording medium having optical properties different from optical properties of the recording medium, wherein the regular spacer arrangement defines at least one location in the recording medium that can be used for retrieving a position of at least one data set (24) stored in the recording medium. The present invention further relates to a method of manufacturing a holographic storage medium and to a method of reading data from a holographic storage medium.

Abstract: The optical analysis system (20) for determining an amplitude of a principal component of an optical signal comprises a multivariate optical element (10) for reflecting the optical signal and thereby weighing the optical signal by a spectral weighing function, and a detector (9, 9P, 9N) for detecting the weighed optical signal. The optical analysis system (20) may further comprise a dispersive element (2) for spectrally dispersing the optical signal, the multivariate optical element being arranged to receive the dispersed optical signal. The blood analysis system (40) comprises the optical analysis system (20) according to the invention.

Abstract: The invention relates to a holographic device for writing data in and/or reading-out data from a holographic information carrier. The holographic information carrier comprises a plurality of patterns recorded with a plurality of corresponding recording multiplexing parameters. The holographic device comprises means for detecting one of the patterns and means for associating the detected pattern with the corresponding recording multiplexing parameter. The invention also relates to a corresponding read-out method and a corresponding recording method.

Abstract: An optical device comprises a light source (301) for generating a radiation beam, a reflective diffractive structure (304) for reflecting and diffracting said radiation beam along an optical path (PP), imaging means (305) for imaging the radiation beam after it has been reflected and diffracted by said reflective diffractive structure, and a holographic beam splitter (303) between said reflective diffractive structure and said imaging means along said optical path. Such an optical device can be used for recording data into a holographic medium.

Abstract: The present invention provides an autonomous calibration of a multivariate based spectroscopic system that is preferably implemented as a multivariate based spectrometer. The spectroscopic system is based on a multivariate optical element that provides a spectral weighting of an incident optical signal. Spectral weighting is performed on the basis of spatial separation of spectral components and subsequent spatial filtering by means of a spatial light modulator. Calibration of the spectroscopic system is based on a dedicated calibration segment of the spatial light modulator, whose position corresponds to a characteristic calibration or reference wavelength of the incident optical signal. Preferably, the calibration or reference wavelength is given by the wavelength of the excitation radiation generated by the optical source that serves to induce scattering processes in a volume of interest.

Abstract: A lithographic apparatus includes a radiation source configured to emit radiation to form a radiation beam, the radiation being of a type which can create plasma in a low pressure environment in the apparatus, and an optical component configured to condition the radiation beam, impart the conditioned radiation beam with a pattern in its cross-section to form a patterned radiation beam, project the patterned radiation beam onto a target portion of a substrate, and/or to detect radiation. The optical component is provided with a plasma quenching structure, the plasma quenching structure being configured to provide electron-ion recombination in, on and/or near the optical component.

Abstract: A lithographic projection apparatus includes an illumination system configured to provide a beam of radiation; a support configured to support a patterning device, the patterning device configured to impart the beam of radiation with a pattern in its cross section; a substrate table configured to hold a substrate, and a projection system configured to project the patterned beam of radiation onto a target portion of the substrate, wherein the illumination system has a radiation source and at least one mirror configured to enhance an output of the source. The illumination system may include a second radiation source and at least one mirror positioned between the radiation sources to image the output of the second source onto the first source, thereby enhancing the output of the source. The radiation sources may be operable to emit radiation in the EUV wavelength range.

Abstract: A lithographic apparatus includes a radiation system that includes a source for producing a radiation beam, a contaminant trap arranged in a path of the radiation beam, and an illumination system configured to condition the radiation beam produced by the source, and a support for supporting a patterning device. The patterning device serves to impart the conditioned radiation beam with a pattern in its cross-section. The apparatus also includes a substrate table for holding a substrate, and a projection system for projecting the patterned radiation beam onto a target portion of the substrate. The contaminant trap includes a plurality of foils that define channels that are arranged substantially parallel to the direction of propagation of the radiation beam. The trap is provided with a gas supply system that is arranged to inject gas into at least one of the channels of the trap.

Abstract: A lithographic apparatus is arranged to project a beam from a radiation source onto a substrate. The apparatus includes an optical element in a path of the beam, a gas inlet for introducing a gas into the path of the beam so that the gas will be ionized by the beam to create electric fields toward the optical element, and a gas source coupled to the gas inlet for supplying the gas. The gas has a threshold of kinetic energy for sputtering the optical element that is greater than the kinetic energy developed by ions of the gas in the electric fields.

Abstract: A lithographic projection apparatus includes reflector assembly, a foil trap, and a housing that is constructed and arranged to contain the reflector assembly and the foil trap. The reflector assembly is connected to the housing via a first wall, and the foil trap is connected to the housing via a second wall. The apparatus also includes a chamber between the foil trap and the reflector assembly. The chamber is defined by the housing, the first wall, and the second wall. The apparatus further includes a pump that is configured to create a vacuum in the chamber.

Abstract: A contamination barrier that passes through radiation from a radiation source and captures debris coming from the radiation source is disclosed. The contamination barrier includes an inner ring, an outer ring, and a plurality of lamellas. The lamellas extend in a radial direction from a main axis, and each of the lamellas is positioned in a respective plane that include the main axis. At least one outer end of each of the lamellas is slidably connected to at least one of the inner and outer ring.

Abstract: A lithographic projection apparatus includes a grazing incidence collector. The grazing incidence collector is made up of several reflectors. In order to reduce the amount of heat on the collector, the reflectors are coated. The reflector at the exterior of the collector has an infrared radiating layer on the outside. The inner reflectors are coated with an EUV reflective layer on the outside.

Abstract: A method for the protection of an optical element of a lithographic apparatus including the optical element and a source of radiation includes providing a material including one or more elements selected from B, C, Si, Ge and/or Sn, and arranging the material such that the source, in use, causes removal of at least part of the material, thereby providing depositable material, and such that at least part of the depositable material deposits on the optical element.

Abstract: A lithographic apparatus includes a source for generating radiation, an illumination system for conditioning the radiation, a patterning device for patterning the conditioned radiation, and a projection system for projecting the patterned radiation onto a target portion of a substrate. The illumination system includes a debris mitigating system for mitigating debris particles that are released with the generation of radiation, and an optical system for collecting the radiation. The debris mitigation system is arranged to directly evaporate the debris particles, or to directly charge the debris particles, or to directly produce a plasma out of the debris particles, or any combination thereof, in a path along which the radiation propagates from the source to the optical system.

Abstract: A lithographic apparatus is disclosed. The lithographic apparatus includes a radiation source that produces EUV radiation, an illumination system that provides a beam of the EUV radiation produced by the radiation source, and a support structure that supports a patterning structure. The patterning structure is configured to impart the beam of radiation with a pattern in its cross-section. The apparatus also includes a substrate support that supports a substrate, and a projection system that projects the patterned beam onto a target portion of the substrate. The radiation source includes a debris-mitigation system that mitigates debris particles which are formed during production of EUV radiation. The debris-mitigation system is configured to provide additional particles for interacting with the debris particles.

Abstract: A lithographic projection apparatus includes an illumination system configured to provide a beam of radiation; a support configured to support a patterning device, the patterning device configured to impart the beam of radiation with a pattern in its cross section; a substrate table configured to hold a substrate, and a projection system configured to project the patterned beam of radiation onto a target portion of the substrate, wherein the illumination system has a radiation source and at least one mirror configured to enhance an output of the source. The illumination system may include a second radiation source and at least one mirror positioned between the radiation sources to image the output of the second source onto the first source, thereby enhancing the output of the source. The radiation sources may be operable to emit radiation in the EUV wavelength range.

Abstract: A lithographic projection apparatus includes a radiation system configured to form a beam of radiation from radiation emitted by a radiation source, as well as a support configured to hold a patterning device, which when irradiated by the beam of radiation provides the beam of radiation with a pattern. A substrate table is configured to hold a substrate, and a projection system is configured to image an irradiated portion of the patterning device onto a target portion of the substrate. The radiation system further includes an aperture at a distance from the optical axis, a reflector which is placed behind the aperture when seen from the source and a structure placed in a low radiation intensive region behind the aperture.

Abstract: A lithographic apparatus includes a source for generating radiation, an illumination system for conditioning the radiation, a patterning device for patterning the conditioned radiation, and a projection system for projecting the patterned radiation onto a target portion of a substrate. The illumination system includes a debris mitigating system for mitigating debris particles that are released with the generation of radiation, and an optical system for collecting the radiation. The debris mitigation system is arranged to directly evaporate the debris particles, or to directly charge the debris particles, or to directly produce a plasma out of the debris particles, or any combination thereof, in a path along which the radiation propagates from the source to the optical system.

Abstract: A lithographic projection apparatus for EUV lithography includes a foil trap, or channel barrier. The foil trap forms an open structure after the source to let the radiation pass unhindered. The foil trap is configured to be rotatable around an optical axis. By rotating the foil trap, an impulse transverse to the direction of propagation of the radiation can be transferred on debris present in the beam. This debris will not pass the foil trap. In this way, the amount of debris on the optical components downstream of the foil trap is reduced. The foil trap may be alternately rotated around the optical axis in a first direction and a second direction opposite the first direction.

Abstract: A radiation system includes a contamination barrier, e.g., a foil trap, between a collector, for example a normal incidence collector, and a radiation source, such that radiation coming from the source passes the foil trap twice. The radiation passes the contamination barrier once before hitting the collector and a second time after reflection by the collector. The foil trap includes lamellas that are parallel to both the radiation coming from the light source, and to the radiation reflected by the collector. The radiation is thus not obstructed by the foil trap. In this way, a normal incidence collector, which is used with a plasma produced source, can be protected from debris coming from a EUV source.