Abstract: The invention relates to a fan case for an aircraft engine in the region of the fan thereof, comprising a plurality of substantially cylindrically arranged fiber-reinforced plastic layers that are joined together, wherein a reinforcement ply made of a glass fiber-reinforced plastic is disposed between an inner layer and an outer layer. According to the invention, the reinforcement ply consists of at least 20 plies of a glass fiber-reinforced plastic, and that deformation layers are disposed on both sides of the reinforcement ply, which deformation layers have a lower strength than the reinforcement ply.

Abstract: The invention relates to a fan case for an aircraft engine in the region of the fan thereof, comprising a plurality of substantially cylindrically arranged fiber-reinforced plastic layers that are joined together, wherein a reinforcement ply made of glass fiber-reinforced plastic is disposed between an inner layer and an outer layer. According to the invention, the reinforcement ply consists of at least 20 plies of a glass fiber-reinforced plastic, and that deformation layers are disposed on both sides of the reinforcement ply, which deformation layers have a lower strength than the reinforcement ply.

Abstract: In order to increase the rigidity of a membrane mask that can be used for ion projection lithography, a second wafer made of the material of the membrane layer is provided in addition to a first wafer. The second wafer is patterned in the same way as the first wafer to form a second carrying ring and is fitted on the membrane layer in a mirror-inverted manner with respect to the first wafer so that the membrane area is arranged between the first and second carrying rings in a centered manner in the direction perpendicular to the membrane plane.

Abstract: A method for producing a perforated mask for particle radiation includes calculating values of an elasticity of adjacent cells of a mask with respect to longitudinal and shear stresses in a main plane of the mask on a model of the desired pattern of mask openings. For the respective individual cells, length and direction of all the edge sections of the openings and cross-sectional areas of the openings are determined. Therefrom, statistical parameters are derived, which are used as a variable in preselected empirical functions to determine the elasticity values of the cells analytically. By linking the elasticity values determined with deformation forces to be expected, the vector field of a distortion of the mask to be expected is calculated by FE calculation. For cutting the mask openings into a blank, a pattern is selected that represents the desired pattern with a distortion being the inverse of the previously calculated distortion.

Abstract: The membrane mask is based on an SOI substrate. In an existing or subsequently produced multilayer semiconductor/insulator/semiconductor-carrier-layer substrate, the inhomogeneous mechanical stresses in the semiconductor layer, which lead to undesirable distortions, are converted at least partly into a homogenous state prior to the structuring of the semiconductor layer. In order to accomplish this, either an additional layer structure is provided on an existing SOI substrate, or a modified layer structure is provided in the fabrication of the SOI substrate, or both.

Abstract: A method for producing a perforated mask for particle radiation includes calculating values of an elasticity of adjacent cells of a mask with respect to longitudinal and shear stresses in a main plane of the mask on a model of the desired pattern of mask openings. For the respective individual cells, length and direction of all the edge sections of the openings and cross-sectional areas of the openings are determined. Therefrom, statistical parameters are derived, which are used as a variable in preselected empirical functions to determine the elasticity values of the cells analytically. By linking the elasticity values determined with deformation forces to be expected, the vector field of a distortion of the mask to be expected is calculated by FE calculation. For cutting the mask openings into a blank, a pattern is selected that represents the desired pattern with a distortion being the inverse of the previously calculated distortion.

Abstract: In order to increase the rigidity of a membrane mask that can be used for ion projection lithography, a second wafer made of the material of the membrane layer is provided in addition to a first wafer. The second wafer is patterned in the same way as the first wafer to form a second carrying ring and is fitted on the membrane layer in a mirror-inverted manner with respect to the first wafer so that the membrane area is arranged between the first and second carrying rings in a centered manner in the direction perpendicular to the membrane plane.

Abstract: The membrane mask is based on an SOI substrate. In an existing or subsequently produced multilayer semiconductor/insulator/semiconductor-carrier-layer substrate, the inhomogeneous mechanical stresses in the semiconductor layer, which lead to undesirable distortions, are converted at least partly into a homogenous state prior to the structuring of the semiconductor layer. In order to accomplish this, either an additional layer structure is provided on an existing SOI substrate, or a modified layer structure is provided in the fabrication of the SOI substrate, or both.

Abstract: For producing an exposure pattern on a resist material layer on a substrate, a mask having a pattern of transparent structures is illuminated with a beam of energetic radiation and the structure pattern is imaged onto the substrate by means of the structured beam within a pattern transfer system such as an ion-beam lithography system. The pattern image produced on the substrate is shifted laterally with respect to the substrate between a plurality of predetermined shift positions and with each shift position the substrate is irradiated for a predetermined time, wherein the width of lateral displacements is smaller than the minimum feature size of the exposure pattern, the blur as determined by the pattern transfer system is not smaller than the width of lateral displacements, and the dimension and/or direction of the structure patterns are incongruent with respect to the lateral displacements.

Abstract: In a masked lithography system (100) a mask (102) with a mask pattern is imaged onto a target (104) by means of a lithography beam (101, 103). For controlling image pattern distortions, a plurality of metrology structures are provided in the mask and are imaged onto a metrology means (150). There, the positions of images of the metrology structures are measured; these positions are compared with respective nominal positions, and a plurality of radiation intensities, each associated to a respective location on the mask, are calculated in a control unit (200). The locations on the mask are heated with the respective radiation intensities by means of a radiation projector means with a radiation source (300) positioned outside the lithography beam path; the heating of the mask thus effected generates distortions in the mask pattern due to local thermal expansion. The distortion control procedure may be iterated in a feedback loop.

Abstract: A particle beam lithography method for imaging a structure pattern onto one or more fields on a substrate (11) by means of electrically charged particles, e.g. ions, in which a particle beam is shaped into a desired beam pattern by means of a mask positioned in the particle beam, converted into a beam pattern by apertures in the mask and projected onto the substrate to form an image of the mask apertures. According to the invention, a plurality of masks is positioned on one mask carrier, thus offering a plurality of aperture patterns which are used for producing structure patterns to be imaged onto respective areas (S) of the substrate. The patterns thus imaged, as a whole, combine together to form e.g. the total pattern of a die-field (D) of the substrate (11).