Patent Number: 051075245
Section: description

DESCRIPTION OF THE PREFERRED EMBODIMENTS FIG. 1 shows a first embodiment of the synchrotron radiation utilizing apparatus according to the present invention. Referring to FIG. 1, synchrotron radiation 4 emitted from an electron beam 2 circulating at a high velocity in an electron accumulation ring 8 of a synchrotron radiation generator (not shown) is radiated in a direction tangential with respect to the orbit of the electron beam 2. The synchrotron radiation 4 is guided by a beam duct 5 whose end is closed so as to maintain a vacuum thereinside. The synchrotron radiation guided through the beam duct 5 penetrates a window (made of a metal, for example, Be) provided at the closed end of the beam duct 5. Objects 9 which are targets to be exposed to the radiated synchrotron radiation 4 are fixedly mounted on supporting members 13 respectively, and these object supporting members 13 are disposed so as to be rotatable relative to a support base 11 supporting the object supporting members 13. Each of the object supporting members 13 is provided with an integral rotary shaft 14, and the support base 11 is combined with an integral rotary body 10 which is provided with an integral rotary shaft 12. In the apparatus having the structure described above, the rotary body 10 is rotated by rotation of the rotary shaft 12, so that the objects 9 can be moved in a direction of 90.degree. relative to the electron orbital plane while maintaining such an angular relation. Therefore, when the rotation velocity of the rotary body 10 is suitably selected, the synchrotron radiation 4 can be directed toward the entire surface of each of the objects 9 in a quantity suitable for exposure. Thus, the apparatus is suitable for semiconductor lithography in which accurate circuit patterning through a mask over a wide area of the objects 9 is especially required. A rotation angle sensor 25 is associated with the rotary shaft 12, and its detection output signal is transmitted to a controlled power supply unit 26. A rotation angle sensor 27 is also associated with each of the rotary shafts 14, and its detection output signal is also transmitted to the controlled power supply unit 26. A rotation drive unit 28 is provided for the rotary shaft 12, and a rotation drive unit 29 is also provided for each of the rotary shafts 14. Controlled power is supplied from the controlled power supply unit 26 to the drive control units 28 and 29 so as to rotate the rotary shafts 12 and 14 at required angular velocities respectively. For example, the rotation drive units 28 and 29 are stepping motors, and the controlled power supply unit 26 supplies controlled power in pulse form. The operation of the drive units 28 and 29 is such that the rotary shafts 12 and 14 are rotated in directions opposite to each other at the same angular velocity. Thus, the object supporting members 13 do not rotate in the horizontal plane but merely make parallel movement in the horizontal plane. On the other hand, the synchrotron radiation 4 is directed to scan the objects 9 at a predetermined angle with respect to the horizontal plane (commonly in a relation parallel to the foundation). Therefore, the objects 9 fixedly mounted on the respective supporting members 13 are uniformly exposed to the synchrotron radiation 4. FIG. 2 shows that the objects 9 to be exposed to the synchrotron radiation 4 are fixedly mounted on the supporting members 13 combined with their rotary shafts 14 respectively. In FIG. 2, the supporting members 13 fixedly mounting the respective objects 9 thereon are thus revolvable relative to the support base 11. Because the object supporting members 13 revolve around the rotary shaft 12 of the support base 11, and the peripheral velocity of the area of the object supporting members 13 remote from the rotary shaft 12 of the support base 11 differs from that of the area near the shaft 12, the area of each of the objects 9 located near the shaft 12 is exposed to a greater quantity of the synchrotron radiation 4 than that of the area located remote from the shaft 12. For example, in the case of semiconductor lithography, the diameter of each wafer 9 is about 10 cm. Therefore, when the distance between the shaft 12 of the support base 11 and the center of each supporting member 13 supporting the wafer 9 is 25 cm, the velocity difference on the wafer 9 is calculated to be 33% at a maximum, as follows: The rotation velocity at a point on the wafer 9 is proportional to the distance between that point and the shaft 12 of the support base 11. Thus, the velocity difference between two points remotest from and nearest to the shaft 12 is expressed as follows: EQU 1-(25-10/2)/(25+10/2)=0.33 However, when, in the arrangement shown in FIG. 2, the object 9 is rotated in one direction around the shaft 14 through the same angle as that of the revolution in the other direction around the shaft 12, the same angle is maintained between an imaginary line 15 drawn on the object 9 and the orbital plane of the electrons. Because the rotation velocity of the object 9 is maintained constant, the exposure quantity of the synchrotron radiation 4 on the object 9 can be maintained constant regardless of the position and time. Further, the synchrotron radiation 4 is very finely converged so that it can accurately scan all over the wafer 9 to ensure uniform exposure. Therefore, while revolving the wafer supporting member 13 around the shaft 12 of the support base 11, the wafer supporting member 13 is rotated around its own shaft 14 in a direction opposite to the revolving direction and at the same angular velocity as that in the revolving movement, so that undesirable non-uniform exposure may not result from the tangential velocity difference between the radially inner and outer areas of the wafer 9 due to the revolution of the wafer supporting member 13 around the shaft 12 of the support base 11. FIG. 3 shows a second embodiment of the present invention, and in FIG. 3, like reference numerals are used to designate like parts appearing in FIG. 1. Referring to FIG. 3, a support block 19 in the form of a frustum of a right cone is mounted at its central axis on a rotary shaft 17. A plurality of object mounting jigs 18 each including a support base 11 and a rotary shaft 10 are perpendicularly mounted on the side surface of the frusto-conical support block 19, and each of the object mounting jigs 18 is rotatable around the axis 12 of the rotary shaft 10. In the apparatus shown in FIG. 3, the combination of the support block 19 and the rotary shaft 10 acts to successively feed the object mounting jigs 18 to a predetermined exposure position, and, when each object mounting jig 18 is fed to the predetermined exposure position, the jig 18 is rotated around the axis 12 of the rotary shaft 10, so that objects 9 can be successively exposed to synchrotron radiation 4. In this case, objects 9 mounted on any one of the object mounting jigs 18 not located at the predetermined exposure position can be replaced as desired. In the apparatus shown in FIG. 3, the side surface of the support block 19 mounted on the rotary shaft 17 is inclined relative to the direction of the synchrotron radiation 4 by an angle equal to the vertical angle of the cone. Therefore, the rotary shaft 17 need not be disposed in parallel to a beam duct 5, and this is desirable from the viewpoint of design in that there is an increased freedom for the layout of the exposure apparatus. FIG. 4 is a partly sectional side elevational view of the support base 11 shown in FIG. 3 to illustrate how the support base 11 and object supporting members 13 are mounted on their rotary shafts. Referring to FIG. 4, the rotary shaft 10 supporting the support base 11 is rotatably journalled in two bearings 22 and 23, while each of the rotary shafts 14 supporting the object supporting members 13 is rotatably journalled in two bearings 20 and 21. When each of the bearings 20, 21, 22 and 23 has the same clearance of 12.5 .mu.m between it and the associated shaft, and the distance between the bearings 20 and 21 and that between the bearings 22 and 23 are more than 10 cm, the ratio between the clearance of the bearings and the distance between the bearings is less than 1/8000. A paper (reported in Applied Physics, Vol. 53, No. 1, 1984, pp. 17-25) describes that, in the case of lithography in which the line width is 0.5 .mu.m, and the spacing between masks and wafers is 20 .mu.m, the dimensional error is to be less than 0.01 .mu.m. when the ratio between the clearance of the bearings and the distance between the bearings is 1/8000 as described above, a maximum inclination of 1/4000=2.5 .times.10.sup.-6 radians is caused due to the clearances of the left and right two bearings. This angle produces, together with the spacing of 20 .mu.m between the masks and the wafers, an error which is calculated as 20 .mu.m .times.2.5.times.10.sup.-6 =0.005 .mu.m. This error may be 0.005.times.2=0.01 .mu.m even when all the clearances of the bearings 20, 21, 22 and 23 are combined. The ratio between the clearance of the bearings and the distance between the bearings can be decreased to less than 1/8000 by employing, for example, angular ball bearings and selecting the distance between the bearings to be more than 10 cm. In this case, the clearance of the angular ball bearings is to be selected to be less than 12.5 .mu.m. In the synchrotron radiation utilizing apparatus of the present invention, the rotary shafts are expected to be rotated at a very low speed lower than one revolution per minute. Therefore, the clearance of the angular ball bearings can be easily set at a value less than 12.5 .mu.m. Even when the clearance of the angular ball bearings cannot be set to be less than 12.5 .mu.m, the distance between the bearings can be easily set at a value more than 10 cm. Displacement of the objects 9 caused by the clearance of the bearings may be parallel movement, besides that attributable to the inclination described above. However, such parallel movement will hardly occur in view of the very low rotation speed of the rotary shafts in the apparatus. Even when such parallel movement may occur, it does not pose any practical problem. This distant is because light emitted from a point light source distant by 5 m from an object makes a very small angle of 12.5.times.10.sup.-6 /5=2.5.times.10.sup.-6 radians with the object making parallel movement of 12.5 .mu.m=12.5.times.10.sup.-6 m. FIG. 5 shows a third embodiment of the present invention, and, in FIG. 5, like reference numerals are used to designate like parts appearing in FIGS. 1 and 3. Referring to FIG. 5, a large-diameter support disc 16 is mounted on a rotary shaft 17 at its central axis. A plurality of object mounting jigs 18 each including a support base 11 and a rotary shaft 10 are mounted on the support disc 16, so that each object mounting jig 18 is rotatable around the axis 12 of the rotary shaft 10 relative to the support disc 16. In the apparatus shown in FIG. 5, the combination of the support disc 16 and the rotary shaft 17 acts to successively feed the object mounting jigs 18 to a predetermined exposure position, and, when each object mounting jig 18 is fed to the predetermined position, the jig 18 is rotated around the axis 12 of the rotary shaft 10, so that objects 9 can be successively exposed to synchrotron radiation. In this case, objects 9 mounted on any one of the object mounting jigs 18 not located at the predetermined exposure position can be replaced as desired. Therefore, the desired replacement operation can be continued without discontinuing the exposure of the objects. It will be understood from the foregoing detailed description of the present invention that a plurality of objects can be efficiently exposed to synchrotron radiation within a short period of time, and a very fine circuit pattern can be uniformly formed on the objects, so that the productivity of semiconductor devices can be greatly improved.