Patent Number: 062748777
Section: claims

1. An electron beam exposure apparatus for forming a pattern on a substrate by exposure using a plurality of electron beams, comprising: an electron beam source for generating a plurality of electron beams in accordance with a pattern to be exposed;  a reduction electron optical system for imaging the plurality of electron beams emitted by said electron beam source on the substrate;  a scanning unit for scanning the plurality of electron beams on the substrate; and  a correction unit for correcting imaging positions of the plurality of electron beams on the basis of correction data corresponding to a distribution of the plurality of electron beams.  an electron source;  a plurality of elementary electron optical systems for forming intermediate images of said electron source; and  a control unit for controlling whether each of said plurality of elementary electron optical systems forms an intermediate image of said electron source.  said scanning unit divides an exposure region on the substrate into a plurality of fields, switches the field to be exposed by said main deflector, and scans the plurality of electron beams in each field using said sub deflector, and  a constant correction amount for imaging positions of the plurality of electron beams is maintained while a pattern is drawn on each field.  the number of electron beams coming from the subarray corresponding to an object to be corrected;  a distance between the subarray corresponding to the object to be corrected, and another subarray that outputs the electron beams; and  the number of electron beams coming from the other subarray.  imaging a plurality of electron beams, which are emitted by an electron beam source in accordance with a pattern to be exposed, via a reduction electron optical system, and scanning the plurality of electron beams on the substrate; and  correcting imaging positions of the plurality of electron beams on the basis of correction data corresponding to a distribution of the plurality of electron beams in synchronism with the scan.  an electron source;  a plurality of elementary electron optical systems for forming intermediate images of said electron source; and  a control unit for controlling whether each of said plurality of elementary electron optical systems forms an intermediate image of said electron source.  a constant correction amount for imaging positions of the plurality of electron beams is maintained while a pattern is drawn on each field.  the number of electron beams coming from the subarray corresponding to an object to be corrected;  a distance between the subarray corresponding to the object to be corrected, and another subarray that outputs the electron beams; and  the number of electron beams coming from the other subarray.  inputting data that defines a pattern to be exposed on a substrate; and  generating correction data used for correcting imaging positions of a plurality of electron beams on the basis of the input data.  inputting data that defines a pattern to be exposed on a substrate; and  generating correction data used for correcting imaging positions of a plurality of electron beams on the basis of the input data.  an electron beam source which generates a plurality of electron beams in accordance with a pattern to be exposed;  a reduction electron optical system which images the plurality of electron beams emitted by said electron beam source on the substrate;  a scanning unit which scans the plurality of electron beams on the substrate; and  a correction unit which corrects imaging positions of the plurality of electron beams on the basis of a distribution of the plurality of electron beams.  an electron source;  a plurality of elementary electron optical systems which form intermediate images of said electron source; and  a control unit which controls whether each of said plurality of elementary electron optical systems forms an intermediate image of said electron source.  said scanning unit divides an exposure region on the substrate into a plurality of fields, switches the field to be exposed by said main deflector, and scans the plurality of electron beams in each field using said sub deflector, and  a constant correction amount for imaging positions of the plurality of electron beams is maintained while a pattern is drawn on each field.  the number of electron beams coming from the subarray corresponding to an object to be corrected;  a distance between the subarray corresponding to the object to be corrected, and another subarray that outputs the electron beams; and  the number of electron beams coming from the other subarray. 2. The apparatus according to claim 1, wherein said correction unit adjusts a focal point position of said reduction electron optical system on the basis of the correction data. 3. The apparatus according to claim 1, wherein said electron beam source comprises: 4. The apparatus according to claim 3, wherein said correction unit adjusts imaging positions of the intermediate images in an axial direction of said reduction electron optical system on the basis of the correction data. 5. The apparatus according to claim 3, wherein said correction unit adjusts imaging positions of the intermediate images in an axial direction of said reduction electron optical system, and a focal point position of said reduction electron optical system on the basis of the correction data. 6. The apparatus according to claim 3, wherein a subarray is formed by a matrix of a plurality of elementary electron optical systems and an entire array is formed by a matrix of a plurality of subarrays. 7. The apparatus according to claim 6, wherein said correction unit corrects imaging positions of the intermediate images in an axial direction of said reduction electron optical system in units of subarrays on the basis of the correction data. 8. The apparatus according to claim 6, wherein said correction unit commonly corrects imaging positions of electron beams coming from all the elementary electron optical systems of the entire array by adjusting a focal point position of said reduction electron optical system on the basis of the correction data, and adjusts imaging positions of the intermediate images in an axial direction of said reduction electron optical system in units of subarrays on the basis of differences between the common correction amount and appropriate correction amounts. 9. The apparatus according to claim 1, wherein said scanning unit comprises a main deflector and a sub deflector for deflecting electron beams emitted by said electron beam source, 10. The apparatus according to claim 1, wherein said correction unit dynamically corrects imaging positions of the plurality of electron beams emitted by said electron beam source on the basis of the correction data. 11. The apparatus according to claim 10, wherein said correction unit corrects the imaging positions of the plurality of electron beams on the basis of the correction data each time a positional relationship between the plurality of electron beams emitted by said electron beam source and the substrate is settled. 12. The apparatus according to claim 6, wherein the correction data is a function having, as variables, at least: 13. The apparatus according to claim 6, wherein the correction data is a function having, as a variable, at least a spacing of electron beams emitted by said electron source. 14. The apparatus according to claim 1, further comprising a calculation unit for generating correction data used for correcting imaging positions of the plurality of electron beams on the basis of data that defines the pattern to be exposed on the substrate. 15. An electron beam exposure method for forming a pattern on a substrate by exposure using a plurality of electron beams, comprising the steps of: 16. The method according to claim 15, wherein the correcting step includes the step of adjusting a focal point position of said reduction electron optical system on the basis of the correction data. 17. The method according to claim 15, wherein said electron beam source comprises: 18. The method according to claim 17, wherein the correcting step includes the step of adjusting imaging positions of the intermediate images in an axial direction of said reduction electron optical system on the basis of the correction data. 19. The method according to claim 17, wherein the correcting step includes the step of adjusting imaging positions of the intermediate images in an axial direction of said reduction electron optical system, and a focal point position of said reduction electron optical system on the basis of the correction data. 20. The method according to claim 17, wherein a subarray is formed by a matrix of a plurality of elementary electron optical systems and an entire array is formed by a matrix of a plurality of subarrays. 21. The method according to claim 20, wherein the correcting step includes the step of correcting imaging positions of the intermediate images in an axial direction of said reduction electron optical system in units of subarrays on the basis of the correction data. 22. The method according to claim 20, wherein the correcting step includes the step of commonly correcting imaging positions of electron beams coming from all the elementary electron optical systems of the entire array by adjusting a focal point position of said reduction electron optical system on the basis of the correction data, and adjusting imaging positions of the intermediate images in an axial direction of said reduction electron optical system in units of subarrays on the basis of differences between the common correction amount and appropriate correction amounts. 23. The method according to claim 15, wherein an exposure region on the substrate is divided into a plurality of fields, the field to be exposed is switched by a main deflector, and the plurality of electron beams in each field is scanned using a sub deflector, and 24. The method according to claim 15, wherein the correcting step includes the step of dynamically correcting imaging positions of the plurality of electron beams emitted by the electron beam source on the basis of the correction data. 25. The method according to claim 24, wherein the correcting step includes the step of correcting the imaging positions of the plurality of electron beams on the basis of the correction data each time a positional relationship between the plurality of electron beams emitted by the electron beam source and the substrate is settled. 26. The method according to claim 20, wherein the correction data is a function having, as variables, at least: 27. The method according to claim 20, wherein the correction data is a function having, as a variable, at least a spacing of electron beams emitted by said electron beam source. 28. The method according to claim 15, further comprising a step of generating correction data used for correcting imaging positions of the plurality of electron beams on the basis of data that defines the pattern to be exposed on the substrate. 29. A method of generating data for controlling an electron beam exposure apparatus of claim 1, comprising the steps of: 30. The method according to claim 29, wherein the correction data generation step includes a step of generating the correction data on the basis of a distribution of electron beams that make up the plurality of electron beams emitted by an electron beam source. 31. The method according to claim 29, wherein the correction data generation step includes a step of generating the correction data for correcting the imaging positions of the plurality of electron beams when a positional relationship between the plurality of electron beams and the substrate is settled. 32. A computer readable program for generating data for controlling an electron beam exposure apparatus of claim 1, comprising the steps of: 33. The program according to claim 32, wherein the correction data generation step includes a step of generating the correction data on the basis of the number of electron beams that make up the plurality of electron beams emitted by an electron beam source. 34. The program according to claim 32, wherein the correction data generation step includes a step of generating the correction data on the basis of a distribution of electron beams that make up the plurality of electron beams emitted by an electron beam source. 35. The method according to claim 32, wherein the correction data generation step includes a step of generating the correction data for correcting the imaging positions of the plurality of electron beams when a positional relationship between the plurality of electron beams and the substrate is settled. 36. A method of manufacturing a device using an electron beam exposure apparatus of claim 1 in some steps. 37. A method of manufacturing a device using an electron beam exposure method of claim 15 in some steps. 38. An electron beam exposure apparatus which forms a pattern on a substrate by exposure using a plurality of electron beams, comprising: 39. The apparatus according to claim 38, wherein said correction unit adjusts a focal point position of said reduction electron optical system on the basis of the distribution of the plurality of electron beams. 40. The apparatus according to claim 38, wherein said electron beam source comprises: 41. The apparatus according to claim 40, wherein said correction unit adjusts imaging positions of the intermediate images in an axial direction of said reduction electron optical system on the basis of the distribution of the plurality of electron beams. 42. The apparatus according to claim 40, wherein said correction unit adjusts imaging positions of the intermediate images in an axial direction of said reduction electron optical system, and a focal point position of said reduction electron optical system on the basis of the distribution of the plurality of electron beams. 43. The apparatus according to claim 40, wherein a subarray is formed by a matrix of a plurality of elementary electron optical systems and an entire array is formed by a matrix of a plurality of subarrays. 44. The apparatus according to claim 43, wherein said correction unit corrects imaging positions of the intermediate images in an axial direction of said reduction electron optical system in units of subarrays on the basis of the distribution of the plurality of electron beams. 45. The apparatus according to claim 43, wherein said correction unit commonly corrects imaging positions of electron beams coming from all the elementary electron optical systems of the entire array by adjusting a focal point position of said reduction electron optical system on the basis of the distribution of the plurality of electron beams, and adjusts imaging positions of the intermediate images in an axial direction of said reduction electron optical system in units of subarrays on the basis of differences between the common correction amount and appropriate correction amounts. 46. The apparatus according to claim 38, wherein said scanning unit comprises a main deflector and a sub deflector which deflect electron beams emitted by said electron beam source, 47. The apparatus according to claim 38, wherein said correction unit dynamically corrects imaging positions of the plurality of electron beams emitted by said electron beam source on the basis of the distribution of the plurality of electron beams. 48. The apparatus according to claim 47, wherein said correction unit corrects the imaging positions of the plurality of electron beams on the basis of the distribution of the plurality of electron beams each time a positional relationship between the plurality of electron beams emitted by said electron beam source and the substrate is settled. 49. The apparatus according to claim 43, wherein the distribution of the plurality of electron beams is expressed by a function having, as variables, at least: 50. The apparatus according to claim 43, wherein the distribution of the plurality of electron beams is expressed by a function having, as a variable, at least a spacing of electron beams emitted by said electron source.