Patent Number: 053902270
Section: claims

1. A semiconductor device manufacturing method comprising: moving a blade integrally with the alignment unit along a surface of the substrate, the blade being disposed between the fixed aperture and the alignment unit;  supplying the blade with cooling liquid;  detecting an alignment mark on the substrate for alignment of the substrate by the alignment unit;  defining an exposure area of the substrate roughly by the fixed aperture and finely by the blade;  further confining the radiation confined by the fixed aperture; and  applying the radiation to the substrate.  disposing a substrate so that an alignment unit is disposed between the substrate, along a path of radiation including X-rays, and a point of origin of divergence of the X-rays;  moving a blade integrally with the alignment unit along a surface of the substrate, the blade being disposed between the point of origin and the alignment unit;  detecting an alignment mark on the substrate for alignment of the substrate by the alignment unit;  applying the radiation, confined by the blade, to the substrate; and  cooling the blade with cooling liquid.  disposing a substrate so that an alignment unit is disposed between the substrate, along a path of radiation including X-rays, and a point of origin of divergence of the X-rays;  moving a blade integrally with the alignment unit along a surface of the substrate, the blade being disposed between the point of origin and the alignment unit;  detecting an alignment mark on the substrate for alignment of the substrate by the alignment unit;  applying the radiation, confined by the blade, to the substrate; and  moving the blade relative to the alignment unit.  a plurality of alignment units each for detecting a relative positional relation between the mask and the substrate, using an alignment mark;  a plurality of stage units for moving said respective alignment units along a plane of the pattern of the mask; and  a plurality of blades having rectilinear edges for limiting the exposure energy, each of said blades being disposed at a position which is nearer to a position where the exposure energy is emitted than said alignment units, and being movable integrally with an associated one of said alignment units,  wherein an amount D of projection of each of said edges in a plane perpendicular to irradiation of the exposure energy into an angle of view of the irradiation area defined by the blade satisfies D&lt;L.sub.A .times.l.sub.min /(2.times.L.sub.M),  where L.sub.M is a distance between the emitting position of the exposure energy and the mask measured in the direction of the irradiation of the exposure energy, L.sub.A is a distance between the edge of said blade to the mask measured in the same direction, and l.sub.min is a minimum width of an exposure area defined by said blades in which the exposure energy is irradiated.  disposing the substrate at a position more remote from a first blade for limiting the exposure beam than an alignment unit;  moving the alignment unit along a surface of the substrate integrally with a second blade disposed nearer to the first blade than the alignment unit;  detecting by the alignment unit an alignment mark provided on the substrate to correctly position the substrate;  exposing the substrate to the exposure beam limited by the first blade and further limited by the second blade; and  supplying the second blade with cooling liquid.  disposing the substrate at a position more remote from a point of origin of divergence of the X-rays than an alignment unit;  moving the alignment unit along a surface of the substrate integrally with a blade disposed nearer to the point of origin than the alignment unit;  detecting by the alignment unit an alignment mark provided on the substrate to correctly position the substrate;  exposing the substrate to the exposure beam limited by the blade; and  supplying the blade with cooling liquid.  disposing the substrate at a position more remote from a point of origin of divergence of the X-rays than an alignment unit;  moving the alignment unit along a surface of the substrate integrally with a blade disposed nearer to the point of origin than the alignment unit;  detecting by the alignment unit an alignment mark provided on the substrate to correctly position the substrate;  exposing the substrate to the exposure beam limited by the blade; and  moving the blade relative to the alignment unit.  a first blade for limiting the exposure energy;  an alignment unit for detecting a relative positional relation between the mask and the substrate using an alignment mark;  a stage unit for moving said alignment unit in a plane of the original; and  a second blade for further limiting the exposure energy limited by said first blade, said second blade being mounted on said alignment unit for integral movement with the alignment unit, wherein said second blade has a width measured in a predetermined direction which is slightly larger than (l.sub.EX -l.sub.min)/2,  where l.sub.EX is a length, measured in the predetermined direction, of the exposure angle of view which is irradiated by the exposure energy and which is defined by said first blade; and l.sub.min is a length measured in the predetermined direction of a minimum exposure region which is defined by said second blade.  an alignment unit for detecting a relative positional relation between the mask and the substrate, using an alignment mark;  a stage unit for moving said alignment unit along a plane of the pattern of the mask;  a blade for limiting the exposure energy, said blade being disposed at a position which is nearer to a position where the exposure energy is emitted than said alignment unit, and being movable integrally with said alignment unit; and  a fine movement mechanism for mounting said blade on said alignment unit for movement relative to said alignment unit.  limiting the exposure energy by a first blade;  detecting a relative positional relation between the mask and the substrate using a movable alignment unit;  further limiting by a second blade the exposure energy limited by the first blade, the second blade being mounted on said alignment unit for integral movement with the alignment unit, wherein the second blade has a width measured in a predetermined direction which is larger than (l.sub.EX -l.sub.min)/2,  where l.sub.EX is a length, measured in the predetermined direction, of the exposure angle of view, which is irradiated by the exposure energy and which is defined by the first blade, and l.sub.min is a length measured in the predetermined direction of a minimum exposure region, which is defined by the second blade.  where l.sub.STG is a distance through which the alignment unit moves in the crossing direction and l.sub.MAX is a length, measured in the predetermined direction, of a maximum exposure region which is defined by the second blade. 2. A microdevice manufacturing method comprising: 3. A microdevice manufacturing method comprising: 4. An apparatus wherein a substrate is exposed to exposure energy containing x-rays through a mask to transfer a pattern of the mask onto the substrate, comprising: 5. A method of exposing a substrate with an exposure beam including X-rays to manufacture a semiconductor device, said method comprising: 6. A method of exposing a substrate with an exposure beam including divergent x-rays to manufacture a semiconductor device, said method comprising: 7. A method of exposing a substrate with an exposure beam including divergent X-rays to manufacture a semiconductor device, said method comprising: 8. An exposure apparatus for exposing a substrate to exposure energy containing x-rays through a mask to transfer a pattern of the mask onto the substrate, comprising: 9. An apparatus according to claim 8, wherein a length of said second blade measured in a direction crossing the predetermined direction is slightly larger than (l.sub.STG +l.sub.max), where l.sub.STG is a distance through which said alignment unit moves in the crossing direction; and l.sub.max is a length, measured in the predetermined direction, of a maximum exposure region which is defined by said second blade. 10. An apparatus according to claim 9, wherein a plural number of sets of said alignment units and said blades are provided, and wherein said blades are mounted on respective alignment units with said blades having linear edges. 11. An apparatus according to claim 10, wherein four of said alignment units are disposed around the mask at orientations which are different by 90 degrees, wherein adjacent ones of said second blades are disposed at different position in a direction of irradiation of the exposure energy. 12. An exposure apparatus wherein a substrate is exposed to exposure energy containing x-rays through a mask to transfer a pattern of the mask onto the substrate, comprising: 13. An exposure method for exposing a substrate to exposure energy containing X-rays through a mask to transfer a pattern of the mask onto the substrate, said method comprising: 14. A method according to claim 13, wherein the exposure energy is synchrotron radiation. 15. A method according to claim 13, wherein a length of the second blade measured in a direction crossing the predetermined direction is slightly larger than (l.sub.STG +l.sub.MAX), 16. A method according to claim 15, further comprising providing a plural number of sets of the alignment units and the blades, and wherein the blades are mounted on respective alignment units with the blades having linear edges. 17. A method according to claim 16, further comprising disposing four of the alignment units around the mask at orientations that are different by 90 degrees, wherein adjacent ones of the second blades are disposed at different positions in a direction of irradiation of the exposure energy.