Patent Number: 
Section: claims

1. A charged particle lithography system for transferring a pattern onto the surface of a target, comprising:a beam generator for generating a plurality of charged particle beamlets, the plurality of beamlets defining a column;a beam stop array having a surface for blocking beamlets from reaching the target surface and an array of apertures in the surface for allowing the beamlets to reach the target surface; anda modulation device for modulating the beamlets to prevent one or more of the beamlets from reaching the target surface or allow one or more of the beamlets to reach the target surface, by deflecting or not deflecting the beamlets so that the beamlets are blocked or not blocked by the beam stop array, the modulation device comprising:a substrate provided with a plurality of apertures arranged in arrays for letting the beamlets pass through the modulation device; anda plurality of modulators arranged in arrays, each modulator provided with electrodes extending on opposing sides of an aperture for generating a voltage difference across the aperture;wherein the modulators are arranged in groups, each group of modulators for directing a group of beamlets towards a single aperture in the beam stop array;wherein individual modulators within each group of modulators have an orientation such that, during generation of a voltage difference across the aperture of the individual modulator for blocking a beamlet onto the blocking surface of the beam stop array, a passing beamlet is directed to a blocking position onto the beam stop array; andwherein the blocking positions of beamlets of the group of beamlets are substantially homogeneously spread around the corresponding single aperture in the beam stop array. 2. The system according to claim 1, wherein each group of modulators is arranged to converge a corresponding group of beamlets at a common point. 3. The system according to claim 2, wherein the individual modulators of each group of modulators are rotated for deflection of the beamlets of a group of beamlets along radial lines extending from the point of convergence of the group of beamlets. 4. The system according to claim 1, wherein each group of modulators is arranged in a rectangular array. 5. The system according to claim 1, wherein each group of modulators is arranged in a radial arrangement around a centrally located axis of the corresponding groups of beamlets. 6. The system according to claim 1, wherein the modulation device includes a plurality of memory elements, each memory element storing a signal for control of one of the modulators. 7. The system according to claim 1, wherein the modulators are arranged in a two dimensional array, and wherein the rows and columns are addressed by bit-lines and word-lines. 8. The system according to claim 1, wherein each group of modulators has a center point, a virtual line substantially perpendicular to the substrate surface of the modulation device through the center point being defined as optical axis; andwherein individual modulators within each group of modulators have an orientation such that, during generation of the voltage difference across the aperture of the individual modulator, a passing beamlet is deflected in a direction along a radial line extending from the optical axis. 9. The system according to claim 8, wherein each group of modulators is arranged to converge a corresponding group of beamlets at a common point, wherein the common point of convergence for the corresponding group of beamlets is on the optical axis of the corresponding group of beamlets. 10. The system according to claim 1, wherein the modulators comprise electrodes having a concave shape. 11. A modulation device for use in a charged particle lithography system for patterning a plurality of charged particle beamlets in accordance with a pattern, the beamlets defining a column, the modulation device serving to modulate the beamlets to prevent one or more of the beamlets from reaching the target surface or allow one or more of the beamlets to reach the target surface, by deflecting or not deflecting the beamlets, the modulation device comprising:a substrate provided with a plurality of apertures arranged in arrays for letting the beamlets pass through the modulation device;a plurality of modulators arranged in arrays, each modulator provided with electrodes extending on opposing sides of an aperture for generating a voltage difference across the aperture;wherein the modulators are arranged in groups, each group of modulators for deflecting or not deflecting a group of beamlets;wherein each group of modulators has a center point, a virtual line substantially perpendicular to the substrate surface of the modulation device through the center point being defined as optical axis; andwherein individual modulators within each group of modulators have an orientation such that, during generation of the voltage difference across the aperture of the individual modulator, a passing beamlet is deflected in a direction along a radial line extending from the optical axis. 12. The device according to claim 11, wherein the modulators comprise electrodes having a concave shape.