Patent Number: 047330872
Section: description

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT FIGS. 1 and 2 illustrate in detail the structure of an ion beam milling apparatus which is an ion beam treating apparatus according to one embodiment of the present invention. In the ion beam milling apparatus as shown in FIG. 1, an internal gear 10 and a plurality of rotary receiving plates 8 are provided on the bottom surface inside an inner wall 1A of a vacuum vessel 1 of the ion beam milling apparatus. Cooling pipes 1C are provided under the bottom surface outside the vacuum vessel 1. The internal gear 10 is secured by bolts 10A to the bottom surface inside the vacuum vessel 1. The internal gear 10 assumes the form of a cylindrical ring and has teeth formed on the inside thereof. A gear 8A is formed along the periphery of each rotary receiving plates 8 and is engaged with the internal gear 10. A spherical hole is formed in the upper portion of the rotary receiving plate 8. A wafer holding portion 7 is provided having at its lower end a spherical portion 7A and holding a wafer 19 at the upper end thereof. The spherical portion 7A is inserted in the spherical hole of the rotary receiving plate 8. The wafer 19 is mounted by a cover 18 on the wafer holding portion 7 which is supported by a tilted link 6. As shown in FIG. 2, the tilted links 6 are coupled by a pin 5A to the stays 5 that are radially fastened to a polygonal plate 4, through an oblong hole 6A formed in the tilted link 6. The polygonal plate 4 is mounted on an upper end 3A of a stepped shaft 3 via bearing means 3C and is allowed to rotate with respect to the stepped shaft 3. The stepped shaft 3 can be slidden up and down owing to bearing means 2C by an actuator 30. An upper end of a shaft 11 of the actuator 30 such as an air cylinder secured to the lower portion outside the vacuum vessel 1 is coupled to a lower end of the stepped shaft 3 through a horizontal link 13 using a pin 11A of the shaft 11 and a pin 3D of the stepped shaft 3. A stay 14 is attached to a lower portion outside the vacuum vessel 1 on the inside of the air cylinder 30. Oblong holes 13A and 13B are formed respectively in the right and left sides of the link 13 with a pin 14A of the stay 14 as a fulcrum. The pin 11A of the shaft 11 is inserted in the oblong hole 13A formed in the horizontal link 13, and the pin 3D of the stepped shaft 3 is inserted in the oblong hole 13B of the horizontal link 13. The rotary receiving plate 8 is supported, as shown in FIG. 3, by a hole 2H formed in a rotary disc 2. A compression spring means 9 is interposed between the rotary disc 2 and the rotary receiving plate 8 so that the rotary receiving plate 8 is pressed onto the bottom surface of the vacuum vessel 1. The rotary disc 2 having a boss 2A with a small diameter is allowed to rotate relative to the stepped shaft 3 owing to the bearing means 2C. The rotary disc 2 is further allowed to rotate relative to the vacuum vessel 1 owing to the bearing means 2F. Moreover, an O-ring 2D and a collar 2E is provided respectively between the stepped shaft 3 and the rotary disc 2. Owing to a gear 15 attached to the stepped shaft 3 and a gear 16 attached to the end of shaft of a motor 17, the rotary disc 2 transmits the rotation of the motor 17 to the tilted link 6 to turn the polygonal plate 4. The gear 15 is mounted on the outerface of the rotary disc 2 through a key 15A. As shown in FIG. 3, the tilted link 6 and the wafer holding portion 7 are combined together through a hole 6B formed in the tilted link 6. A projection 6C of the tilted link 6 and a projection 2J of the rotary disc 2 are coupled together by pulling spring means 20 to prevent the wafer holding portion 7 from floating when it is tilted. The wafer holding portion 7 and the rotary receiving plate 8 are contacted to each other along a spherical portion 7A. The spherical portion 7A is formed together with the wafer holding portion 7 at lower end thereof. In the spherical portion 7A of the wafer holding portion 7 is formed a groove 7B of a width H as shown in FIG. 4. A pin 8B with an outer diameter d.sub.1 fastened to the rotary receiving plate 8 is fitted into the groove 7B. The width H of the groove 7B is slightly greater than the outer diameter d.sub.1 of the pin 8B of the rotary receiving plate 8, so that the pin 8B of the rotary receiving plate 8 is allowed to slide in the groove 7B of the spherical portion 7A. The pin 8B is inserted by a depth l.sub.1 in the groove 7B which has an maximum depth L; i.e., the pin 8B is floated by l.sub.2. A tilting mechanism of this embodiment of the present invention is comprised of the connecting mechanism for transmitting the rotation of the rotary receiving plate 8 to the wafer holding portions 7, tilted links 6 for tilting the wafer holding portions 7, the polygonal plate 4 for coupling the tilted links 6, the shaft 3 being coupled to the tilted links 6 as an unitary structure and moving in the rotary disc 2, and moving means for moving the shaft 3, so that the distances are maintained equal between an ion source and the respective wafers 19. Namely, the respective wafers 19 on the wafer holding portions 7 are disposed on same circle line surrounding of the outersurface of the stepped shaft 3. The distances between the ion source and the respective wafers 19 are maintained equal. Accordingly, the ion beam emitted from the ion source irradiates uniformly the respective wafers 19 and treats uniformly the respective wafers 19. The respective wafers 19 are irradiated with the ion beam maintaining the uniform intensity. Operation of the above embodiment of the present invention will now be described. As shown in FIG. 1, first, if the actuator 30 moves in a direction e, the stepped shaft 3 is moved in a direction f, whereby the polygonal plate 4 moves in a direction g and the wafer holding portions 7 are outwardly tilted in a direction h due to the tilted link 6. Conversely, if the actuator 30 is moved in a direction a, the stepped shaft 3 moves in a direction b and the polygonal plate 4 moves in a direction c to assume the state indicated by a two-dot chain line, whereby the wafer holding portions 7 are inwardly tilted in a direction d due to the tilted link 6. When the turn in a direction i of the gear 16 produced by the motor 17 is transmitted to the rotary disc 2 via the gear 15, the rotary receiving plates 8 revolves in a direction j with the stepped shaft 3 as a center. At the same time, the rotary receiving plates 8 rotate in a direction k while revolving in the direction j, since they are in mesh with the internal gear 10 that is secured to the vacuum vessel 1. A relationship between the rotary receiving plates 8 and the wafer holding portions 7, when the abovementioned operation is being carried out, will be explained below in conjunction with FIGS. 5, 6 and 7. FIG. 5 illustrates the state where the wafer holding portions 7 are outwardly tilted and the grooves 7B of the spherical portions 7A are located on the outermost side. Due to the rotary disc 2, the rotary receiving plates 8 starts to rotate from this position, and the wafer holding portions 7 and the rotary receiving plates 8 rotate in synchronism due to the pin 8B of the rotary receiving plates 8. Namely, the wafer holding portions 7 starts to rotate in the direction k. FIG. 6 illustrates the state where the rotary receiving plates 8 are rotated by 90 degrees from the state of FIG. 5, and FIG. 7 illustrates the state where the rotary receiving plates 8 are further rotated by 180 degrees from the state shown in FIG. 5. Thus, the wafer holding portions 7 are allowed to rotate and revolve in the vacuum vessel 1 being tilted in any direction. As shown in FIG. 1, the wafer holding portions 7 can be maintained at any angle within a range of .+-..beta. degrees (usually .+-.30 degrees). According to this embodiment of the present invention, therefore, the respective or individual wafers are tilted, and are rotated and revolved maintaining the thus tilted angle. The distances between the respective wafers on the wafer holding portions and the ion source are maintained equal by the tilting mechanism. Therefore, the surfaces of the respective or individual wafer are irradiated with the ion beam maintaining the uniform intensity, making it possible to prevent adhesion of matter by sputtering and to prevent the affect of the secondary sputtering among the respective wafers. Accordingly, thin films for semiconductors can be finely patterned maintaining high precision.