Patent Number: 
Section: claims

1. An EUV (Extreme Ultraviolet) collector mirror for an EUV light source, the EUV light source being configured for irradiating a target with laser light from a driver laser to turn the target into plasma, the EUV collector mirror comprising a multilayered reflecting surface with grooves and being configured for collecting EUV light from the plasma to a focal spot, the grooves being arranged in a concentric fashion, wherein the grooves are configured for diffracting at least light at a wavelength which is the same as that of the laser light from the driver laser. 2. The EUV collector mirror according to claim 1, wherein a wavelength of light to be diffracted by the grooves is approximately 10.6 μm. 3. The EUV collector mirror according to claim 1, wherein the driver laser is a carbon dioxide (CO2) laser. 4. The EUV collector mirror according to claim 1, wherein the EUV collector mirror has a first focus and a second focus. 5. The EUV collector mirror according to claim 4, wherein the grooves are arranged concentrically with respect to an axis going through the first focus and the second focus. 6. The EUV collector mirror according to claim 1, wherein the EUV collector mirror is one of an ellipsoidal mirror and a paraboloidal mirror. 7. The EUV collector mirror according to claim 6, wherein the grooves are arranged concentrically with respect to an axis of symmetry of the multilayered reflecting surface of the one of the ellipsoidal mirror and the paraboloidal mirror. 8. The EUV collector mirror according to claim 1, wherein a distance between a nadir of one groove and that of an adjacent groove is in a range of 300 μm to 800 μm. 9. The EUV collector mirror according to claim 1, wherein a distance between a nadir of one groove and that of an adjacent groove is in a range of 1.54 μm to 400 μm. 10. The EUV collector mirror according to claim 1, wherein a distance between a nadir of one groove and that of an adjacent groove is in a range of 400 μm to 800 μm. 11. The EUV collector mirror according to claim 1, wherein a distance between a nadir of one groove and that of an adjacent groove is in a range of 1.54 μm to 800 μm. 12. The EUV collector mirror according to claim 1, wherein the multilayered reflecting coating comprises 100 to 1000 pairs of stacked Mo/Si layers. 13. The EUV collector mirror according to claim 1, whereinthe multilayered reflecting surface comprises pairs of stacked Mo/Si layers, anda nadir of each groove reaches approximately 250 th to 300 th pair of the stacked Mo/Si layers from a surface of the one of the mirrors. 14. The EUV collector mirror according to claim 13, further comprising a substrate with the multilayered reflecting surface, whereinthe multilayered reflecting surface includes approximately 50 pairs of the stacked Mo/Si layers between the nadir and the substrate. 15. The EUV collector mirror according to claim 1, further comprising a surface coating on a surface of the multilayered reflecting surface. 16. The EUV collector mirror according to claim 15, wherein a material of the surface coating includes ruthenium. 17. A method for manufacturing an EUV collector mirror according to claim 1, the method comprising the step of irradiating the multilayered reflecting surface with a particle beam through a mask to form the grooves configured for diffracting light at a wavelength different from that of the EUV light. 18. The method according to claim 17, wherein the particle beam is an ion beam. 19. The method according to claim 17, wherein the irradiating step includes rotating the EUV collector mirror about an axis of symmetry of the EUV collector mirror when irradiating the multilayered reflecting surface with the particle beam. 20. The method according to claim 19, wherein the irradiating step further comprises the steps of:irradiating the multilayered reflecting surface with the particle beam delivered in a first direction to form a first groove;changing an irradiation direction of the particle beam to a second direction from the first direction; andirradiating the multilayered reflecting surface with the particle beam delivered in the second direction to form a second groove. 21. The method according to claim 19, wherein the first and second directions are substantially perpendicular to the multilayered reflecting surface to which the particle beam is delivered. 22. The EUV collector mirror according to claim 1, wherein the grooves are configured for diffracting light to be reflected or scattered by the target. 23. The EUV collector mirror according to claim 1, wherein the grooves are configured for diffracting the laser light to be reflected or scattered by the target. 24. The EUV collector mirror according to claim 1, wherein the grooves are configured for diffracting the laser light to be reflected or scattered by the target to focus the reflected or scattered laser light on a position. 25. The EUV collector mirror according to claim 1, wherein the grooves are configured for diffracting the laser light to be reflected or scattered by the target to focus the reflected or scattered laser light on a position where no focal spot on which the EUV light is focused is placed. 26. The EUV collector mirror according to claim 1, wherein pitches of the grooves are varied in accordance with locations on the multilayered reflecting surface. 27. An EUV light source for generating an EUV light for an exposure device, the EUV light source being configured for irradiating a target with laser light from a driver laser to turn the target into plasma from which the EUV light is emitted, the EUV light source comprising:a chamber;a target supply device configured for supplying the target into the chamber; andan EUV collector mirror in the chamber, the EUV collector mirror comprising a multilayered reflecting surface with grooves and being configured for collecting the EUV light from the plasma to a focal spot, the grooves being arranged in a concentric fashion, whereinthe grooves are configured for diffracting at least light at a wavelength which is the same as that of the laser light from the driver laser. 28. The EUV light source according to claim 27, wherein a wavelength of light to be diffracted by the grooves is approximately 10.6 μm. 29. The EUV light source according to claim 27, wherein the driver laser is a carbon dioxide (CO2) laser. 30. The EUV light source according to claim 27, further comprising a magnetic field generator for generating a magnetic field around the plasma. 31. The EUV light source according to claim 30, wherein the magnetic field generator comprises a plurality of coils for generating the magnetic field. 32. The EUV light source according to claim 27, wherein the target supply device is configured for providing the target to the chamber in the form of droplets. 33. The EUV light source according to claim 32, wherein a material for the target is Sn. 34. The EUV light source according to claim 27, wherein the chamber contains at least one of a hydrogen gas, a halogen gas, a hydrogenated halogen gas, and an argon gas. 35. The EUV light source according to claim 34, further comprising a heater for heating the EUV collector mirror. 36. The EUV light source according to claim 34, further comprising a radio wave generator configured for generating a radio wave to excite the at least one of the hydrogen gas, the halogen gas, the hydrogenated halogen gas, and the argon gas in the chamber. 37. The EUV light source according to claim 27, further comprising a light shielding device placed between the EUV collector mirror and the exposure device, and configured for passing light to be collected to the focal spot by the EUV collecting mirror. 38. The EUV light source according to claim 37, wherein the light shielding device is placed between a region where the target is turned into the plasma and the exposure device. 39. The EUV light source according to claim 37, wherein the light shielding device includes a cooling device for cooling the light shielding device. 40. The EUV light source according to claim 37, wherein the light shielding device includes a through-hole through which the light to be collected to the focal spot passes. 41. The EUV light source according to claim 40, wherein the through-hole of the light shielding device has a diameter equal to or less than around 10 mm. 42. The EUV light source according to claim 40, wherein the through-hole of the light shielding device has a diameter in a range of 4 mm to 6 mm. 43. The EUV light source according to claim 27, wherein the EUV collector mirror has a first focus and a second focus. 44. The EUV light source according to claim 43, wherein the grooves are arranged concentrically with respect to an axis going through the first focus and the second focus. 45. The EUV light source according to claim 27, wherein the EUV collector mirror is one of an ellipsoidal mirror and a paraboloidal mirror. 46. The EUV light source according to claim 45, wherein the grooves are arranged concentrically with respect to an axis of symmetry of the multilayered reflecting surface of the one of the ellipsoidal mirror and the paraboloidal mirror. 47. The EUV light source according to claim 27, wherein a distance between a nadir of one groove and that of an adjacent groove is in a range of 300 μm to 800 μm. 48. The EUV light source according to claim 27, further comprising a surface coating on a surface of the multilayered reflecting surface. 49. The EUV light source according to claim 48, wherein a material of the surface coating includes ruthenium. 50. The EUV light source according to claim 27, wherein the EUV collector mirror is positioned to first reflect the EUV light from the plasma. 51. The EUV light source according to claim 27, wherein the EUV collector mirror is positioned so that the EUV light from the plasma is directly incident on the EUV collector mirror. 52. An EUV (Extreme Ultraviolet) collector mirror for an EUV light source, the EUV light source being configured for irradiating a target with laser light from a driver laser to turn the target into plasma, the EUV collector mirror comprising a multilayered reflecting surface with grooves and being configured for collecting EUV light from the plasma to a focal spot, the grooves being arranged in a concentric fashion, whereinthe EUV collector mirror is an ellipsoidal mirror. 53. The EUV collector mirror according to claim 52, wherein the EUV collector mirror has a first focus and a second focus, and is configured for focusing on around the second focus the EUV light from the plasma to be generated around the first focus. 54. The EUV collector mirror according to claim 53, wherein the grooves are configured for diffracting at least light at a wavelength which is the same as that of the laser light from the driver laser, the diffracted light being focused on a position where no focal spot on which the EUV light is focused is placed. 55. The EUV collector mirror according to claim 52, wherein the multilayered reflecting surface is configured for focusing the EUV light on the focal spot by Bragg reflection.