Patent Number: 
Section: claims

1. In an X-ray source that generates X-rays from a plasma produced by directing pulsed laser light onto a target material in a vacuum chamber evacuated to a subatmospheric pressure, a device for directing an X-ray flux from the plasma to a downstream optical system, comprising: an optical element situated such that X-rays from the plasma are incident on the optical element, the optical element having an axis of rotational symmetry and being configured to direct the X-ray flux to the downstream optical system; and  a rotational actuator situated relative to the optical element and configured to rotate the optical element about the axis. 2. The device of  claim 1 , wherein the optical element is an X-ray reflective mirror. claim 1 3. The device of  claim 2 , wherein the mirror is selected from a group consisting of multi-layer mirrors, grazing-incidence mirrors, spherical mirrors, paraboloidal mirrors, planar mirrors, ellipsoidal mirrors, and a spherical mirrors. claim 2 4. The device of  claim 2 , wherein the mirror comprises a reflective surface having a profile selected from a group consisting of spherical, paraboloidal, planar, ellipsoidal, a spherical, and combinations thereof. claim 2 5. The device of  claim 1 , wherein the optical element is an optical filter or X-ray diffractive element. claim 1 6. The device of  claim 1 , further comprising: claim 1 a position detector situated and configured to detect a position of the optical element;  a controller to which the position detector is connected; and  positional actuator connected to the controller and to which the optical element is mounted, the positional actuator being configured, when commanded by the controller, to move the optical element as required to maintain a desired position of the optical element, based on a signal from the position detector. 7. The device of  claim 6 , wherein the positional actuator comprises an X-direction linear stage, a Y-direction linear stage, and a Z-direction linear stage. claim 6 8. The device of  claim 6 , wherein the position detector comprises a contact-needle displacement gauge. claim 6 9. The device of  claim 6 , wherein the position detector comprises a light source directed at the optical element and a light receiver oriented so as to receive light reflected from the optical element, the light source being selected from the group consisting of lasers, light-emitting diodes, and lamps. claim 6 10. The device of  claim 1 , wherein the optical element is situated within the vacuum chamber. claim 1 11. An X-ray optical system including an X-ray source that generates X-rays from a plasma produced by directing pulsed laser light onto a target material in a vacuum chamber evacuated to a subatmospheric pressure, the X-ray optical system comprising a device as recited in  claim 1 . claim 1 12. An X-ray source, comprising: a vacuum chamber;  an X-ray generator situated within the vacuum chamber and configured to produce a plasma sufficiently energized so as to produce X-rays;  an optical element contained in the vacuum chamber and situated such that X-rays from the plasma are incident on the optical element, the optical element having an axis of rotational symmetry and being configured to direct the X-ray flux in a downstream direction; and  an actuating device situated relative to the optical element and configured to rotate the optical element about the axis. 13. The X-ray source of  claim 12 , wherein the X-ray generator is a laser-plasma X-ray device. claim 12 14. The X-ray source of  claim 12 , wherein the X-ray generator is a plasma-discharge X-ray device. claim 12 15. The X-ray source of  claim 12 , wherein the optical element is an X-ray reflective mirror. claim 12 16. The X-ray source of  claim 12 , wherein the optical element is an optical filter. claim 12 17. The X-ray source of  claim 12 , further comprising: claim 12 a position detector situated and configured to detect a position of the optical element;  a controller to which the position detector is connected; and  a positional actuator connected to the controller and to which the optical element is mounted, the positional actuator being configured, when commanded by the controller, to move the optical element as required to maintain a desired position of the optical element, based on a signal from the position detector. 18. The X-ray source of  claim 17 , wherein the positional actuator comprises an X-direction linear stage, a Y-direction linear stage, and a Z-direction linear stage. claim 17 19. The X-ray source of  claim 17 , wherein the position detector comprises a contact-needle displacement gauge. claim 17 20. The X-ray source of  claim 17 , wherein the position detector comprises a light source directed at the optical element and a light receiver oriented so as to receive light reflected from the optical element, the light source being selected from the group consisting of lasers, light-emitting diodes, and lamps. claim 17 21. An X-ray optical system, comprising an X-ray source as recited in  claim 12 . claim 12 22. In a method for producing an X-ray flux, propagating along a propagation axis, from a plasma generated by exciting a target material, a method for producing an X-ray flux that remains axially symmetrical despite production of flying particles by the plasma, the method comprising: providing an optical element situated so as to direct the X-ray flux, propagating from the plasma, to a downstream optical system, the optical element having an axis of rotation and being subject to deposition of particles of flying debris from the plasma; and  rotating the optical element about the axis of rotation whenever X-rays are being produced by the plasma. 23. The method of  claim 22 , wherein the optical element is selected from a group consisting of X-ray reflective mirrors, X-ray diffractive elements, and filters. claim 22 24. The method of  claim 22 , further comprising the step of monitoring a position of the optical element as the optical element is rotated about the axis of rotation. claim 22 25. The method of  claim 24 , further comprising the step of correcting a position of the optical element whenever monitoring of the position of the optical element reveals a positional change that exceeds a preset specification. claim 24