Abstract: A method for producing a component from two plates, which are electrically isolating, at least one is optically transparent, and between them at least one planar conductor section and at least one isolator section are formed, comprises bonding the plates at mutually facing bonding faces, wherein a metal layer is arranged therebetween, and processing the metal layer by local heating using laser radiation such that the metal layer is converted into the at least one isolator section in a part region, and the at least one conductor section is formed adjacent thereto. To form the at least one isolator section, the light path of the laser radiation and the component are moved relative to each other to convert the metal layer into the at least one isolator section over a line or area. Bonding faces of metallic bond layers are polished. The plates are bonded by atomic diffusion bonding.

Abstract: A method for producing a component from two plates, which are electrically isolating, at least one is optically transparent, and between them at least one planar conductor section and at least one isolator section are formed, comprises bonding the plates at mutually facing bonding faces, wherein a metal layer is arranged therebetween, and processing the metal layer by local heating using laser radiation such that the metal layer is converted into the at least one isolator section in a part region, and the at least one conductor section is formed adjacent thereto. To form the at least one isolator section, the light path of the laser radiation and the component are moved relative to each other to convert the metal layer into the at least one isolator section over a line or area. Bonding faces of metallic bond layers are polished. The plates are bonded by atomic diffusion bonding.

Abstract: A method for processing a metal film (1) embedded in a carrier (2) includes the step of heating the metal film (1) in such a way that the metal film (1) is transformed in a subregion into at least one insulator section (3). The metal film (1) is preferably locally heated by laser radiation (4). Also described is a component (10, 11, 12, 13) which is produced by the method and includes an electrostatic clamp, a drive mechanism which is adapted for moving a workpiece under the action of electrical fields, a resistor element or a display device, for example.

Abstract: A method for processing a metal film (1) embedded in a carrier (2) includes the step of heating the metal film (1) in such a way that the metal film (1) is transformed in a subregion into at least one insulator section (3). The metal film (1) is preferably locally heated by laser radiation (4). Also described is a component (10, 11, 12, 13) which is produced by the method and includes an electrostatic clamp, a drive mechanism which is adapted for moving a workpiece under the action of electrical fields, a resistor element or a display device, for example.

Abstract: A method of producing a high resolution expanded analog gray scale mask is described. Using an inorganic chalcogenide glass, such as a selenium germanium, coated with a thin layer of silver, a gray scale mask may be produced with accurate control of the size, uniformity and variance of the pixels. The selenium germanium glass is composed of column structures arranged perpendicularly to the substrate giving a possible edge precision of 100 .ANG.. The column structures also prevent undercutting during the etching process, thus permitting pixels to be placed close together. Accordingly, selenium germanium may be used as a high resolution gray scale mask with an expanded analog gray scale. The gray scale mask may be used to impress information as a modulated thickness on a selenium germanium photoresist layer on an inorganic substrate. The selenium germanium photoresist layer may then transfer the gray scale to the substrate.