Patent Number: 
Section: claims

1. In an arrangement for the generation of EUV radiation based on a gas discharge plasma in which a cathode and an anode are arranged in a cylindrically symmetric manner and a pre-ionized work gas is supplied to the cathode end, comprising:an insulation areas being exclusively provided as a suitably shaped annular vacuum gap that is formed and sized depending on the product of gas pressure (p) and interelectrode distance (d) of the cathode and anode between surfaces that face one another outside a desired discharge region, in which plasma is generated for insulating the cathode and anode from one another for reliable suppression of electron arcing. 2. The arrangement according to claim 1, wherein a device for the pre-ionization of the work gas is provided inside the centrally arranged cathode. 3. The arrangement according to claim 2, wherein the anode is a ring electrode enclosing at least the cathode end with a close interelectrode distance (d) and forming a discharge chamber. 4. The arrangement according to claim 3, wherein a pre-ionization electrode with a projecting tubular insulator is arranged in a centrally symmetric manner inside the cathode and opens into a cavity of the cathode for pre-ionization of the work gas, wherein a surface sliding discharge can be generated at the insulator by a pre-ionization pulse between the pre-ionization electrode and the cathode so that the work gas which is ionized in this way flows out of the cavity via at least one through-channel at the cathode end into the discharge chamber, where it is converted into dense, hot plasma by a main discharge pulse. 5. The arrangement according to claim 4, wherein a through-channel is arranged coaxially and centrally. 6. The arrangement according to claim 4, wherein a plurality of uniformly distributed through-channels are directed along an outer conical surface concentrically through a common point on the axis of symmetry to an inner surface of the anode. 7. The arrangement according to claim 6, wherein the through-channels degenerate to form an annular gap. 8. The arrangement according to claim 4, wherein the cathode is provided at its end with a rounded electrode collar which projects into the interior of the anode that circles the discharge chamber, wherein the vacuum insulation areas located between the anode and cathode are protected against debris particles from the plasma and against electrode consumption by the electrode collar. 9. The arrangement according to claim 8, wherein the cathode end inside the electrode collar has a concave curvature and is the location where the dense, hot plasma is formed. 10. The arrangement according to claim 9, wherein a pocket hole is incorporated in the center of the concave curvature of the cathode. 11. The arrangement according to claim 4, wherein the cathode has a small cavity and long through-channels, wherein the through-channels are arranged coaxially and are shaped in such a way that, at the cathode end in the discharge chamber, primary electrically conducting ionization channels are directed through a common point on the axis of symmetry of the discharge chamber to a surface of the anode. 12. The arrangement according to claim 4, wherein the cathode has a large cavity and short through-channels, wherein the cavity extends into the vicinity of a concave cathode end, and the through-channels are arranged in such a way that primary electrically conducting ionization channels are directed from the ionized work gas flowing into the discharge chamber, through a common point on the axis of symmetry of the discharge chamber, to a surface of the anode. 13. The arrangement according to claim 4, wherein the surface discharge provided for the pre-ionization of the work gas is provided at the inner side of the insulator, and the pre-ionization electrode is shorter than the tubular insulator and is arranged with a central gas inlet inside the tubular insulator. 14. The arrangement according to claim 4, wherein the surface discharge used for the pre-ionization of the work gas is provided on the outer side of the insulator, and the pre-ionization electrode projecting into the cavity of the cathode is arranged with a central gas inlet and a tubular insulator located on the outer side. 15. The arrangement according to claim 14, wherein the cavity of the cathode is expanded in width and, in the shape of a spherical hood, is provided with short through-channels over a concave cathode end, wherein the through-channels are directed through a common point to the inner surface of the anode. 16. The arrangement according to claim 14, wherein the cavity of the cathode is shaped so as to taper conically toward the cathode end and is provided directly with the gas inlet and has a circular opening at the concave cathode end, wherein the pre-ionization electrode is inserted coaxially into this opening so that an annular gap is left open relative to the discharge chamber through which the work gas is directed in primary electrically conducting ionization channels in the shape of an outer cone surface through a common point on the axis of symmetry of the discharge chamber to an inner surface of the anode. 17. The arrangement according to claim 16, wherein the pre-ionization electrode has a pocket hole at its surface facing the discharge chamber in the axis of symmetry and has its own cooling channels. 18. The arrangement according to claim 14, wherein the cavity of the cathode tapers conically toward the cathode end and has a circular opening at the concave cathode end, the pre-ionization electrode being snugly inserted therein with inner and outer insulators, wherein the pre-ionization electrode has a plurality of gas inlets which are directed to the surface of the anode as through-channels through the inner and outer insulators via a common point on the axis of symmetry. 19. The arrangement according to claim 14, wherein an auxiliary electrode which is insulated from the cathode is inserted into the cavity of the cathode, wherein the auxiliary electrode has the cavity provided for the pre-ionization of the work gas, and the pre-ionization electrode with outer insulator is arranged so as to project into the cavity, and in that at least one corresponding through-channel is provided in the cathode and auxiliary electrode for the exit of the pre-ionized work gas into the discharge chamber. 20. The arrangement according to claim 19, wherein a plurality of through-channels are arranged in the auxiliary electrode and the cathode along an outer conical surface in order to form primary ionization channels from the cavity into the discharge chamber, wherein the through-channels are directed to an inner surface of the anode through a common point on the axis of symmetry of the discharge chamber. 21. The arrangement according to claim 19, wherein the auxiliary electrode is insulated from the cathode end by another cavity in which a voltage pulse for accelerating the ionized work gas can be applied additionally between the auxiliary electrode and the cathode. 22. The arrangement according to claim 1, wherein means for generating a magnetic field ({right arrow over (B)};{right arrow over (B)}1,{right arrow over (B)}2) are provided in order to increase the dielectric strength of the vacuum insulation, particularly with larger interelectrode distances (d) in the vacuum insulation space, wherein the flux lines of the magnetic field are oriented orthogonal to those of the electric field between the anode and cathode. 23. The arrangement according to claim 22, wherein concentric magnet rings are arranged on the inner side and outer side in the vacuum insulation space, the magnetic field being formed in radial direction therebetween, wherein a body is arranged toward the transition area in order to prevent inhomogeneities in the electric field between the anode and cathode. 24. The arrangement according to claim 22, wherein concentric magnet rings are arranged on the inner side and the outer side in the vacuum insulation space, around which are formed two opposed, circularly extending magnetic fields ({right arrow over (B)}1,{right arrow over (B)}2), wherein a body is arranged toward the transition area to prevent inhomogeneities in the electric field between the anode and cathode in the transition area. 25. The arrangement according to claim 22, wherein concentric magnet rings comprising a plurality of individual permanent magnets are arranged for generating the magnetic fields ({right arrow over (B)};{right arrow over (B)}1,{right arrow over (B)}2). 26. The arrangement according to claim 25, wherein the concentric magnet rings comprise a plurality of individual NdFeB magnets. 27. The arrangement according to claim 22, wherein concentric magnet rings comprising a plurality of individual electromagnets are arranged for generating the magnetic fields. 28. The arrangement according to claim 1, wherein a pre-ionization unit has through-channels to a gap-shaped transition area between the vacuum insulation space and discharge chamber, wherein the work gas that is pre-ionized in this way is introduced into the discharge chamber through the transition area of the vacuum insulation between the cathode and anode and is contracted by the main current pulse to form the hot, dense plasma. 29. The arrangement according to claim 1, wherein the gas inlet is arranged in an outer vacuum insulation space with a large interelectrode distance (d) between the cathode and anode, and the gas pressure (p) and interelectrode distance (d) are adjusted in such a way that the product of gas pressure (p) and interelectrode distance (d) for a work gas that is used exceeds a defined value in order to achieve a spontaneous ignition of the work gas in the annular vacuum insulation space. 30. The arrangement according to claim 29, wherein grooves or similar structures are incorporated in the outer vacuum insulation space in at least one of the oppositely located electrode surfaces of the cathode and anode to increase the interelectrode distance for the purpose of a local increase in the product of gas pressure (p) and interelectrode distance (d) and to initiate the spontaneous ignition in a plurality of primary ionization channels. 31. The arrangement according to claim 29, wherein the electrodes for the plasma-generating gas discharge, cathode and anode, are outfitted with cooling channels for cooling. 32. The arrangement according to claim 31, wherein additional auxiliary electrodes provided for pre-ionization of the work gas are provided with cooling channels. 33. The arrangement according to claim 21, wherein deionized water is used as coolant. 34. The arrangement according to claim 32,erein deionized water is used as coolant. 35. arrangement according to claim 1, wherein xenon, lithium vapor or tin vapor, or gaseous tin compounds are used as work gas.