Patent Number: 051577003
Section: claims

1. An exposure apparatus usable with synchrotron radiation generating means for injecting electrons into a ring to produce synchrotron radiation, said apparatus comprising: exposure means for exposing a wafer, through a mask, to the synchrotron radiation introduced from the synchrotron radiation generating means through a window;  intensity detecting means for detecting an intensity distribution of the synchrotron radiation; and  control means for controlling said exposure means on the basis of the intensity distribution provided by said detecting means immediately after injection of the electrons into the ring.  detecting means for detecting an intensity of X-rays after injection of electrons to generate the synchrotron radiation; and  means for calculating an X-ray intensity during an exposure operation on the basis of a result of detection by said detecting means and on an attenuation curve of the injected electrons.  a shutter for controlling exposure;  a sensor for detecting an intensity of exposure radiation at a portion of an exposure area;  a controller for controlling said shutter; and  a signal processor for calculating a cumulative amount of exposure on the basis of the intensity of the exposure radiation detected by said sensor at the exposure area portion upon a preliminary actuation of said shutter by said controller, and for supplying an output to said controller,  wherein said controller effects control of said shutter in accordance with the output supplied from said signal processor, to control an actual exposure operation.  a shutter for controlling exposure;  a sensor for detecting an intensity of exposure radiation at a position of an exposure area;  a shutter driver for opening and closing said shutter; and  calculating means for receiving outputs of said sensor when said shutter is opened and when said shutter is closed, in synchronism with opening and closing of said shutter by said shutter driver, and for processing the outputs to calculate an intensity of the exposure radiation,  wherein said calculating means calculates the intensity of the exposure radiation by storing and processing information from said semiconductor sensor immediately before and after actuation of said shutter by said shutter driver.  first detecting means for detecting an intensity of X-ray rays, corresponding to an exposure area; and  second detecting means, disposed outside of the exposure area, for detecting attenuation of the synchrotron radiation.  a shutter for controlling an exposure period;  a semiconductor sensor for detecting an intensity of exposure radiation;  a wafer stage;  a wafer stage driver for driving said wafer stage;  a shutter driver for opening and closing said shutter; and  calculating means for receiving an output of said semiconductor sensor in synchronism with opening and closing of said shutter and for processing the output to calculate an intensity of the exposure radiation,  wherein said wafer stage, upon a detection of exposure radiation intensity by said sensor, retracts the wafer from exposure radiation, so that the wafer is not exposed to the exposure radiation during a detection.  a shutter for controlling an exposure period;  a semiconductor sensor for detecting an intensity of exposure radiation;  a wafer stage;  a wafer stage driver for driving said wafer stage;  a shutter driver for opening and closing said shutter;  calculating means for receiving an output of said semiconductor sensor in synchronism with opening and closing of said shutter by said shutter driver, and for processing the output to calculate an intensity of the exposure radiation; and  an auxiliary shutter for preventing the wafer from being exposed to the radiation during detection of the exposure radiation intensity by said sensor.  a stage for supporting a member to be exposed;  optical control means for controlling radiation projected from the exposure radiation source to the member;  optical detecting means for detecting one of an intensity of the radiation of the radiation source and the intensity of the radiation on a surface of the member to be exposed;  driving profile determining means, coupled with said optical control means and said optical detecting means, for determining a driving profile of said optical control means based on the intensity on the surface as a function of position of the surface and based on the intensity of the radiation source, to provide a uniform amount of exposure on the surface; and  driving profile compensating means for one of expanding and contracting a time axis of the driving profile in accordance with a change in the intensity of the radiation source.  a stage for supporting a member to be exposed;  exposure control means, disposed in a radiation path between the radiation source and said stage, including a movable member for selectively limiting the radiation from said radiation source to the member;  determining means for determining a driving speed for providing a constant amount of exposure of the member to radiation, despite any attenuation, with time, of an intensity of the radiation to the member; and  driving means for driving said movable member of said exposure control means in accordance with the driving speed determined by said determining means.  a stage for supporting a member to be exposed;  exposure control means, disposed in a radiation path between the radiation source and said stage, including a movable member for selectively limiting the radiation from said radiation source to the member;  determining means for determining a driving speed for providing a constant amount of exposure of the member to radiation, despite any attenuation, with time, of an intensity of the radiation to the member; and  driving means for driving said stage in accordance with the driving speed determined by said determining means.  injecting electrons into a ring to generate a synchrotron radiation beam;  detecting an intensity distribution of the synchrotron radiation beam immediately after injection of the electrons in said injecting step;  controlling exposure of a substrate to the synchrotron radiation beam on the basis of the detected intensity distribution.  injecting electrons into a ring to generate a synchrotron radiation beam;  detecting an intensity distribution of x-rays in the synchrotron radiation beam after injection of the electrons in said injection step;  determining an intensity of the x-rays during a predetermined period on the basis of the detection in said detecting step and an attenuation curve of the injected electrons; and  controlling exposure of a substrate to the synchrotron radiation beam on the basis of the determination.  opening a shutter for preliminary exposure of an exposure region;  detecting exposure radiation through the shutter by a sensor located at a position in the exposure region when the shutter is preliminarily opened in said opening step;  calculating an exposure amount of the position on the basis of the detection, and providing an information signal relating to the exposure amount;  exposing a substrate to the exposure radiation, while the shutter is controlled on the basis of the information signal, to expose the substrate to the radiation for semiconductor manufacturing.  providing a sensor for detecting exposure radiation;  operating a shutter for controlling exposure with the exposure radiation;  detecting, immediately before and after the operation of the shutter an output of the sensor when the shutter is closed and an output of the sensor when the shutter is opened;  determining a value related to an intensity of the exposure radiation on the basis of the outputs detected in said detecting step.  providing an exposure control mechanism for controlling exposure of a substrate to exposure radiation, and operating the exposure control mechanism on the basis of a driving profile;  performing one of expanding and contracting a time base of the driving profile in accordance with a change in an intensity property of the exposure radiation determined on the basis of detecting the exposure radiation to determine a corrected driving profile; and  operating the exposure control mechanism in accordance with the corrected profile to expose the substrate to the exposure radiation.  providing an exposure control mechanism for controlling exposure of a substrate to exposure radiation, and driving a movable member at a predetermined speed by the exposure control mechanism;  determining the driving speed of the movable member in accordance with attenuation of intensity of the exposure radiation with time; and  moving the movable member at the predetermined driving speed, while exposing the substrate.  providing an exposure control mechanism for controlling exposure of a substrate to exposure radiation, and driving a stage carrying the substrate at a predetermined speed by the exposure control mechanism;  determining the driving speed of the stage in accordance with attenuation of intensity of the exposure radiation with time; and  moving the stage at the predetermined driving speed, while exposing the substrate.  obtaining information, related to intensity of x-rays contained in a synchrotron radiation beam supplied to an exposure region, by a first detector disposed in the exposure region;  retracting the first detector outside the exposure region;  detecting attenuation of the synchrotron radiation beam with a second sensor disposed outside the exposure region; and  controlling exposure of the exposure region on the basis of outputs of the first and second sensors. 2. An apparatus according to claim 1, wherein said control means comprises means for controlling said exposure means on the basis of the intensity distribution of the synchrotron radiation immediately after one of mounting and exchanging the window. 3. An apparatus according to claim 1, wherein said intensity detecting means comprises a wafer carrying stage for carrying the wafer and further comprising an X-ray detector mounted thereon. 4. An apparatus according to claim 1, wherein said exposure means comprises a shutter for controlling the amount of radiation introduced, and wherein said control means controls the shutter in accordance with the intensity distribution detected by said intensity detecting means. 5. An X-ray exposure apparatus using synchrotron radiation, said apparatus comprising: 6. An exposure apparatus, comprising: 7. An apparatus according to claim 6, further comprising means for moving said sensor in the exposure area, and wherein said signal processor calculates an amount of exposure from a plurality of exposure area portions. 8. An apparatus according to claim 6, wherein said controller comprises means for correcting control of said shutter on the basis of the cumulative amount of exposure fed back thereto from said signal processor. 9. An exposure apparatus, comprising: 10. An X-ray exposure apparatus for transferring by synchrotron radiation a pattern of a mask onto a member coated with a sensitive resist, said apparatus comprising: 11. An exposure apparatus comprising: 12. An exposure apparatus comprising: 13. An exposure apparatus usable with an exposure radiation source, said apparatus comprising: 14. An apparatus according to claim 13, wherein the radiation source is an X-ray source, and said optical control means comprises a movable aperture. 15. An apparatus according to claim 13, wherein the radiation source is a synchrotron radiation source, and said optical control means comprises an actuator for swinging a mirror. 16. An exposure apparatus usable with a radiation source, said apparatus comprising: 17. An apparatus according to claim 16, wherein said exposure control means comprises a movable aperture stop. 18. An apparatus according to claim 16, wherein said exposure control means comprises a movable mirror. 19. An exposure apparatus usable with a radiation source, said apparatus comprising: 20. An exposure method for manufacturing semiconductor devices, comprising: 21. A method according to 20, further comprising providing a window, which is substantially transparent to the synchrotron radiation beam, between the ring and the substrate, and effecting said detecting step with respect to the beam passed through the window. 22. A method according to claim 21, further comprising effecting detecting step immediately after the window is one of mounted and replaced. 23. A method according to claim 21, further comprising effecting said detecting step using a detector mounted on a stage for carrying the substrate. 24. A method according to claim 23, wherein the detector includes a x-ray detector, and further comprising detecting the x-rays contained in the synchrotron radiation beam with the x-ray detector. 25. A method according to claim 21, further comprising using a shutter in said exposure controlling step. 26. An exposure method for manufacturing semiconductor devices, comprising: 27. A method according to claim 26, further comprising providing a window, which is substantially transparent to the synchrotron radiation beam, between the ring and the substrate, and effecting said detecting step to the beam passed through the window. 28. A method according to claim 27, further comprising effecting said detecting step using a detector mounted on a stage for carrying the substrate. 29. A method according to claim 28, further comprising using a shutter in said controlling step. 30. An exposure method for manufacturing semiconductor devices, comprising: 31. A method according to claim 30, further comprising repeating the preliminary exposure for different positions of the sensor, and providing the information signal on the basis of exposure amounts calculated for the different positions. 32. A method according to claim 30, further comprising providing a window which is substantially transparent to the radiation and effecting said detecting step to radiation passed through the window. 33. A method according to claim 30, wherein the radiation includes x-rays in synchrotron radiation. 34. An exposure method for manufacturing semiconductor devices, comprising: 35. A method according to claim 34, further comprising providing a window which is substantially transparent to the radiation and effecting said detecting step to radiation passed through the window. 36. A method according to claim 35, wherein the radiation includes x-rays in synchrotron radiation. 37. An exposure method for manufacturing semiconductor devices, comprising: 38. A method according to claim 37, further comprising providing a window which is substantially transparent to the radiation and effecting said detecting step to radiation passed through the window. 39. A method according to claim 38, wherein the radiation includes x-rays in synchrotron radiation. 40. An exposure method for manufacturing semiconductor devices, comprising: 41. A method according to claim 40, further comprising providing a window which is substantially transparent to the radiation, and detecting radiation passed through the window. 42. A method according to claim 41, wherein the radiation includes x-rays in synchrotron radiation. 43. An exposure method for manufacturing semiconductor devices, comprising: 44. A method according to claim 43, further comprising providing a window which is substantially transparent to the radiation and detecting radiation passed through the window. 45. A method according to claim 44, wherein the radiation includes x-rays in synchrotron radiation. 46. An exposure method for manufacturing semiconductor devices, comprising: 47. A method according to claim 46, further comprising providing a window which is substantially transparent to the radiation and effecting said detecting step to radiation passed through the window.