Patent Number: 062857436
Section: claims

1. A soft X-ray source comprising: a mirror having a focal point, the mirror being parabolic or ellipsoidal;  a nozzle delivering a target material to a plasma generation point substantially coincident with the focal point; and  a laser source delivering a pulsed laser beam to the plasma generation point,  wherein a plasma is generated at the plasma generation point upon irradiation by the pulsed laser beam, the plasma emitting soft X-rays that are formed into X-ray beams by the mirror,  wherein the X-ray beams are parallel if reflected from the parabolic mirror and converging if reflected from the ellipsoidal mirror, and  wherein one of an axis of the nozzle and an axis of the pulsed laser beam is coaxial with an axis of the mirror.  a protective plate that protects the mirror from the target material; and  a target material recovery device that collects the target material when the protective plate is protecting the mirror.  ejecting a target material from a nozzle towards a plasma generation point;  irradiating the target material with a pulsed laser beam; and  forming soft X-ray beams by reflecting soft X-rays emitted by the plasma from a mirror, the mirror being parabolic or ellipsoidal, the soft X-ray beams being parallel or converging,  wherein the pulsed laser beam is directed towards substantially a focal point of the mirror, the focal point being substantially coincident with the plasma generation point, and  wherein one of an axis of the nozzle and an axis of the pulsed laser beam is coaxial with an axis of the mirror.  a nozzle ejecting a target material towards a plasma generation point;  a mirror having a focal point that substantially corresponds to the plasma generation point, the mirror being parabolic or ellipsoidal; and  a laser source delivering at least two pulsed laser beams to the plasma generation point,  wherein a plasma is generated at the plasma generation point in response to irradiation by the two pulsed laser beams, and  wherein the plasma emits the soft X-rays, the soft X-rays being reflected into parallel or converging X-ray beams by the mirror, and  wherein one of an axis of the nozzle and an axis of the pulsed laser beam is coaxial with an axis of the mirror.  ejecting a target material towards a plasma generation point from a nozzle;  irradiating the target material at the plasma generation point with at least two pulsed laser beams so as to form a plasma; and  reflecting soft X-rays emitted by the plasma from a mirror to form beams, the mirror being parabolic or ellipsoidal,  wherein the beams are parallel if reflected from the parabolic mirror and converging if reflected from the ellipsoidal mirror,  wherein a focal point of the mirror is substantially coincident with the plasma generation point, and  wherein one of an axis of the nozzle and an axis of the pulsed laser beam is coaxial with an axis of the mirror.  wherein the soft X-ray reflective mirror has a focal point corresponding to the plasma generation point.  a low pressure vessel;  a nozzle in the low pressure vessel, the nozzle ejecting a target material towards a plasma generation point;  a mirror having a focus corresponding to the plasma generation point, the mirror being parabolic or ellipsoidal; and  a laser irradiating the target material at the plasma generation point to convert a portion of the target material into a plasma,  wherein electromagnetic energy emitted by the plasma is reflected from the mirror to form beams,  wherein the beams are parallel if reflected from the parabolic mirror and converging if reflected from the ellipsoidal mirror.  a source of electromagnetic waves in a wavelength range between 0.1 nm to 300 nm;  a source of target material, the target material being one of a liquid, liquid droplets, fine particles, gas and clusters;  an irradiation source for irradiating the target material and converting the target material into a plasma that emits radiation in the wavelength range between 0.1 nm to 300 nm,  wherein the source of electromagnetic waves includes an optical element for shaping the radiation into the electromagnetic waves,  wherein a reflective surface of the optical element is substantially axially symmetrical,  wherein the irradiation source irradiates the target material from a direction of the optical element,  wherein the source of the target material does not block a path of the electromagnetic waves, and  wherein the electromagnetic waves are parallel if reflected from the parabolic mirror and converging if reflected from the ellipsoidal mirror.  wherein a central axis of the source of the target material and a central axis of the mirror coincide, and  wherein an optical axis of the irradiation source does not pass through the source of the target material.  wherein the target material is irradiated from a plurality of directions. 2. The soft X-ray source of claim 1, further including a reflective surface on a concave face of the mirror that reflects the soft X-rays emitted from the plasma. 3. The soft X-ray source of claim 2, wherein the reflective surface does not reflect the soft X-rays towards the nozzle. 4. The soft X-ray source of claim 1, wherein the target material is a liquid. 5. The soft X-ray source of claim 1, wherein the target material is a solid. 6. The soft X-ray source of claim 5, further including: 7. The soft X-ray source of claim 1, wherein the target material is one of a gas and clusters. 8. The soft X-ray source of claim 1, further including a hole in the mirror, wherein the pulsed laser beam is delivered through the hole to the plasma generation point. 9. A method of generating soft X-rays comprising the steps of: 10. The method of claim 9, wherein the mirror includes a reflective surface that reflects the soft X-rays emitted by the plasma and forms the soft X-ray beams. 11. An apparatus for generating soft X-rays comprising: 12. The apparatus of claim 11, wherein the pulsed laser source delivers at least four pulsed laser beams to the plasma generation point. 13. The apparatus of claim 11, wherein the nozzle is positioned away from the plasma generation point, such that the pulsed laser beams do not impact the nozzle. 14. The apparatus of claim 11, further including at least two apertures in the mirror, wherein the at least two pulsed laser beams are delivered through the at least two apertures to the plasma generation point. 15. The apparatus of claim 14, wherein a number of the apertures corresponds to a number of the pulsed laser beams. 16. The apparatus of claim 11, further including a soft X-ray filter in a path of the X-ray beams, the soft X-ray filter including a first portion that passes the soft X-rays, and a second portion that blocks the soft X-rays. 17. The apparatus of claim 11, further including a soft X-ray reflection mirror that reflects the soft X-rays towards the mirror, the soft X-ray reflection mirror having a focal point substantially coincident with the plasma generation point. 18. The apparatus of claim 11, wherein the mirror includes a multi-layer reflective film having a thickness distribution so that the mirror has the same reflection wavelength throughout its surface for soft X-rays emitted from the focal point of the mirror. 19. A method of generating soft X-rays comprising the steps of: 20. The method of claim 19, wherein the nozzle is positioned away from the plasma generation point such that the two pulsed laser beams do not impact the nozzle. 21. The method of claim 19, further including the step of passing a first portion of the soft X-rays through a soft X-ray filter, and blocking a second portion of the beams with the soft X-ray filter. 22. The method of claim 19, further including the step of reflecting the soft X-rays emitted by the plasma from a soft X-ray reflective mirror towards the mirror, 23. An electromagnetic wave source comprising: 24. An exposure apparatus comprising: 25. The exposure apparatus of claim 24, wherein the optical element includes a mirror, the mirror being parabolic or ellipsoidal, 26. The exposure apparatus of claim 24, wherein the target material jets out of the source of the target material in a direction along an axis of rotational symmetry of the optical element, and 27. The exposure apparatus of claim 26, wherein the plurality of directions are distributed at substantially equal angular intervals. 28. The exposure apparatus of claim 26, wherein beams from the irradiation source directed at the target material from the plurality of directions have substantially the same intensity, and irradiate the target material at substantially the same time. 29. The exposure apparatus of claim 26, wherein beams from the irradiation source directed at the target material irradiate the target material from one of the same direction and different directions at the same time. 30. The exposure apparatus of claim 24, wherein the optical element includes a multi-layer reflective film whose film having a thickness distribution so that the optical element has the same reflection wavelength throughout the reflective surface for electromagnetic waves emitted from a focal point of the optical element. 31. The exposure apparatus of claim 24, further including a filter to block a portion of the electromagnetic waves in the wavelength range between 0.1 nm to 300 nm emitted from a focal point of the optical element. 32. The exposure apparatus of claim 24, further including a reflective mirror reflecting the electromagnetic waves in the wavelength range between 0.1 nm to 300 nm generated at a focal point of the optical element, the reflective mirror having a focal point substantially coinciding with the focal point of the optical element and reflecting the electromagnetic waves in the wavelength range between 0.1 nm to 300 nm towards the optical element. 33. The exposure apparatus of claim 24, wherein the target material is one of xenon, krypton, oxygen, a compound of oxygen and a mixture gas including any one of xenon, krypton, oxygen, and the compound of oxygen.