Patent Number: 
Section: claims

1. A maskless lithography system for direct, nano-scaleable structuring of a substrate disposed in a vacuum chamber using a charged particle beam, and a high voltage present within the vacuum chamber, comprising:a mounting table for supporting the substrate when the substrate is structured;a beam source for generating the charged particle beam;an addressable pattern generating system which is configured as a plate system; anda data transmission system configured to transmit a structure pattern to be produced to the pattern generating system as a set of pattern data generated via computer, wherein said data transmission system comprises electro-optical converters and opto-electrical converters; whereinsaid data transmission system is an opto-electrical free-space optical beam connection system and is configured to distribute the pattern data, which has been optically converted by the electro-optical converters via light exit locations and light entry locations and in adjustably oriented free-space optical beams between the light exit locations and the light entry locations, to the opto-electrical converters, with the light entry locations residing inside the vacuum chamber and being arranged in an array, and the opto-electrical converters being associated with the pattern generating system with respect to the transmitted pattern data;the opto-electrical converters are spatially disposed directly within the plate system;the number N of the electro-optical converters is adapted to the rate of pattern data to be transmitted, based on their predetermined conversion rate; andoptical deflection arrangements are disposed in the free-space optical beams inside the vacuum chamber. 2. The maskless lithography system according to claim 1, further comprising the vacuum chamber, wherein the light exit locations are disposed outside the vacuum chamber, and wherein the free-space optical beams are guided into the vacuum chamber through a transparent window in the vacuum chamber. 3. The maskless lithography system according to claim 2, wherein the window is shielded by a cover against external light and electromagnetic fields, outside of where the free-space optical beams pass through. 4. The maskless lithography system according to claim 1, wherein collimating and focusing microlenses are disposed at least one of the light exit locations and the light entry locations. 5. The maskless lithography system according to claim 1, wherein at least one of the light entry locations and the light exit locations are arranged in an array. 6. The maskless lithography system according to claim 5, wherein the array of the light exit locations is imaged by imaging optics onto the array of the light entry locations. 7. The maskless lithography system according to claim 1, wherein at least one of the light entry locations and the light exit locations are formed by the ends of light waveguides. 8. The maskless lithography system according to claim 7, wherein the ends of the light waveguides, when formed by light fibres, are combined into a fibre array plug. 9. The maskless lithography system according to claim 1, wherein the electro-optical converters serving as light exit locations are formed by active emitting elements. 10. The maskless lithography system according to claim 1, wherein the opto-electrical converters serving as light entry locations are formed by active receiving elements. 11. The maskless lithography system according to claim 1, wherein the light entry locations and the light exit locations are arranged inside the vacuum chamber. 12. The maskless lithography system according to claim 1, wherein the addressable pattern generating system comprises a blanking plate having a plurality of addressable apertures for modulating the charged particle beam based on the set of pattern data, wherein the opto-electrical converters are distributed over the blanking plate and are allocated there to groups of the plurality of addressable apertures. 13. The maskless lithography system according to claim 1, wherein the plate system includes a plate and the opto-electrical converters are disposed on one of the main surfaces of the plate, the plate having a plurality of addressable elements for modulating the charged particle beam based on the pattern data. 14. A maskless lithography system for direct, nano-scaleable structuring of a substrate disposed in a vacuum chamber using a charged particle beam, and a high voltage present in the vacuum chamber, comprising:a mounting table for disposing the substrate on same when the substrate is structured,a beam source for generating the charged particle beam;an addressable pattern generating system which is configured as a plate system;a data transmission system configured to transmit a structure pattern to be produced to the pattern generating system as a set of pattern data generated with computer aid; whereinsaid data transmission system comprises electro-optical converters and opto-electrical converters; whereinsaid data transmission system is an opto-electrical free-space optical beam connection system and is configured to distribute the pattern data which has been optically converted by the electro-optical converters via light exit locations and light entry locations and in adjustably oriented free-space optical beams between the light exit locations and the light entry locations, to the opto-electrical converters, with the light entry locations residing inside the vacuum chamber and being arranged in an array, and the opto-electrical converters being associated with the pattern generating system with respect to the transmitted pattern data;the opto-electrical converters are spatially disposed directly within the plate system; andthe number N of the electro-optical converters is adapted to the rate of pattern data to be transmitted, based on their predetermined conversion rate; andthe pattern generating system is configured to be powered, at least partially, by energy transmitted via the free-space optical beams from the light exit locations to the light entry locations. 15. The maskless lithography system according to claim 14, further comprising the vacuum chamber, wherein the light entry locations are arranged inside of the vacuum chamber and the light exit locations are disposed outside the vacuum chamber, and wherein the free-space optical beams are guided into the vacuum chamber through a transparent window in the vacuum chamber. 16. The maskless lithography system according to claim 14, wherein the pattern generating system is configured to load an energy storage with the energy transmitted via the free-space optical beams from the light exit locations to the light entry locations, and to power internal processes within the pattern generating system for energy stored within the energy storage. 17. A maskless lithography system for direct, nano-scaleable structuring of a substrate disposed in a vacuum chamber using a charged particle beam, and a high voltage, comprisinga vacuum chamber within which the high voltage is present;a mounting table for disposing the substrate on same when the substrate is structured,a beam source for generating the charged particle beam;an addressable pattern generating system which is configured as a plate system;a data transmission system configured to transmit a structure pattern to be produced to the pattern generating system as a set of pattern data generated with computer aid; whereinsaid data transmission system comprises electro-optical converters and opto-electrical converters; whereinsaid data transmission system is an opto-electrical free-space optical beam connection system and is configured to distribute the pattern data which has been optically converted by the electro-optical converters via light exit locations and light entry locations and in adjustably oriented free-space optical beams between the light exit locations and the light entry locations, to the opto-electrical converters, with the light entry locations residing inside the vacuum chamber and being arranged in an array, and the opto-electrical converters being associated with the pattern generating system with respect to the transmitted pattern data;the opto-electrical converters are spatially disposed directly within the plate system;the light entry locations are arranged inside the vacuum chamber and the light exit locations are disposed outside the vacuum chamber, and the free-space optical beams are guided into the vacuum chamber through a transparent window in the vacuum chamber;the number N of the electro-optical converters is adapted to the rate of pattern data to be transmitted, based on their predetermined conversion rate; andadditional electro-optical converters are disposed within the pattern generating system, for generating monitoring and control signals and guiding them in a back direction via further free-space optical beams onto additional opto-electrical converters; andan adjustment system being configured to, using said monitoring and control signals as received via the additional opto-electrical converters as feedback signals, align the free-space optical beams with the light entry locations by:correcting a position of the light exit locations; orcorrecting a position of the optics in a beam path along which the free-space optical beams are guided from the light exit locations to the light entry locations. 18. The maskless lithography system according to claim 7, wherein the adjustment system is disposed in the beam path of the free-space optical beam connection system. 19. A method of maskless lithography, comprising:generating a charged particle beam using a beam source within a vacuum chamber;directing the charged particle beam to an addressable pattern generating system configured as a plate system;supplying pattern data to a plurality of electro-optical converters, and converting the pattern data to corresponding optical signals respectively carried by a plurality of free-space optical beams;directing the plurality of free-space optical beams via light exit locations and light entry locations being spaced apart from each other to multiple opto-electrical converters, and converting the optical signals corresponding to the set of pattern data to control the plate system; whereinthe light entry locations are arranged inside the vacuum chamber and the light exit locations are disposed outside the vacuum chamber, and the free-space optical beams are guided into the vacuum chamber through a transparent window in the vacuum chamber;the opto-electrical converters are spatially disposed directly within the plate system;by use of additional electro-optical converters disposed within the pattern generating system, generating monitoring and control signals and guiding them in a back direction via further free-space optical beams onto additional opto-electrical converters; andusing the monitoring and control signals as received via the additional opto-electrical converters as feedback signals, aligning the free-space optical beams with the light entry locations by:correcting a position of the light exit locations; orcorrecting a position of the optics in a beam path along which the free-space optical beams are guided from the light exit locations to the light entry locations. 20. The method of claim 19, wherein a path of the charged particles at least partially overlaps with a path of the free-space optical beams traveling in between the light exit locations and the light entry locations. 21. A maskless lithography system for direct, nano-scaleable structuring of a substrate disposed in a vacuum chamber using a charged particle beam, and a high voltage present within the vacuum chamber, the system comprising:a mounting table for disposing the substrate on same when the substrate is structured,a beam source for generating the charged particle beam;an addressable pattern generating system; anda data transmission system configured to transmit a structure pattern to be produced to the pattern generating system as a set of pattern data generated with computer aid; whereinsaid data transmission system comprises electro-optical converters and opto-electrical converters; whereinsaid data transmission system is an opto-electrical free-space optical beam connection system and is configured to distribute the pattern data which has been optically converted by the electro-optical converters via light exit locations and light entry locations and in adjustably oriented free-space optical beams between the light exit locations and the light entry locations, to the opto-electrical converters, with the light entry locations residing inside the vacuum chamber and being arranged in an array, and the opto-electrical converters being associated with the pattern generating system with respect to the transmitted pattern data;the data transmission system is further configured such that a path of the charged particles at least partially overlaps with a path of the free-space optical beams travelling in between the light exit locations and the light entry locations;additional electro-optical converters are disposed within the pattern generating system, for generating monitoring and control signals and guiding them in a back direction via further free-space optical beams onto additional opto-electrical converters; andthe maskless lithography system further comprises an automatable adjustment system being configured to, using said monitoring and control signals as received via the additional opto-electrical converters as feedback signals, align the free-space optical beams with the light entry locations by:correcting a position of the light exit locations; orcorrecting a position of the optics in a beam path along which the free-space optical beams are guided from the light exit locations to the light entry locations. 22. The maskless lithography system according to claim 1, further comprising the vacuum chamber, wherein the light entry locations are arranged inside of the vacuum chamber and the light exit locations are disposed outside the vacuum chamber, and wherein the free-space optical beams are guided into the vacuum chamber through a transparent window in the vacuum chamber. 23. The maskless lithography system according to claim 22, wherein the light exit locations are disposed directly at the window from the outside. 24. The maskless lithography system according to claim 22, wherein the light exit locations are disposed orthogonally beneath the window, and wherein the free-space optical beams are guided by an additional optical deflection arrangement through the window into the vacuum chamber. 25. The maskless lithography system according to claim 22, wherein the window is recessed into the vacuum chamber.