TW518425B - Birefringence minimizing fluoride crystal optical VUV microlithography lens elements and optical blanks therefore - Google Patents

Abstract

A birefringence minimizing fluoride crystal VUV optical lithography lens element is provided for use with lithography wavelengths < 230 nm. The VUV lithography lens element has an optical axis encompassed by a lens perimeter with the fluoride crystal lens having a variation in crystallograpic orientation direction which tilts away from the optical center axis towards the lens perimeter to provide minimal birefringence. The invention includes a birefrigence minimizing fluoride crystal optical lithography lens blank with a variation in crystallographic orientation direction across the blank.

Description

518425 A7 _ '丨! ,, 1 1 _B7 V. Description of the Invention (|) Printed by the Consumer Cooperative of the Central Standards Bureau of the Ministry of Economic Affairs Background of the Invention: The present invention relates to optical light lithographic printing elements and hair embryos and special winter about optical low light stone In the lithographic printing system of crystal lens elements and optical elements for photolithography, the system uses vacuum ultraviolet (VUV) wavelengths below 200 nm, preferably below 193 nm, preferably below 175 nm, and more preferably Below 164nm, for example, a vaporized UV projection light lithography system with a wavelength in the I57nm region is used. The use of a projection optical light stone with a wavelength of less than 200nm vacuum ultraviolet light $ The printing system has the advantage of achieving a smaller size. This system uses vacuum ultraviolet wavelengths in the wavelength region below 157nm, which has the potential to improve collective circuits with smaller form factors. Optical lithographic printing systems currently used by the semiconductor industry that manufacture collective circuits continue to develop towards lower light wavelengths such as generally 248 nm, but commercial use of vacuum ultraviolet wavelengths below 200 nm such as 193 nm and 157 nm The vacuum ultraviolet wavelength transmission in the empty ultraviolet excimer laser region is hindered by the influence of optical material characteristics. Available optical materials and their optical characteristics at the short-wavelength lithographic printing wavelength have been hindered below the chirp wavelength; they are used industrially in optical lithographic printing systems. Use of fluoride, for example, calcium fluoride crystals as optical lens blanks and optical lens elements in optical lithography. Because the birefringence of the optical material of the fluoride crystal is hindered and has a negative effect, the crystal birefringence has an effect on the light lithography transmitted through it. Printing light has an effect. Listen to the commission 2_m wavy 157nm area, such as the F2 excimer laser emission spectrum of the collective industry manufacturing vacuum line vacuum vacuum ultraviolet lithography printing advantages, there are advantages in light paper size application) 2lGx297_j ----- Ψ —, —— (Please read the precautions on the back before filling out this page) Order 518425 V. Description of the invention (2 Printed photolithography lithography crystal lens for generalized crystal lenses Elementary phase and the requirement of the blank with the smallest birefringence optical element. Nikon's European EP1001314A2 patent application describes a durable optical system for projection irradiation. For good durability, it uses fluorinated mother crystals to prevent highly irradiated light lithographic printing energy density. For example, ArF excimer light lithography lasers cause damage. Nicon's U.S. Patent No. 61174 describes the use of UV laser laser light lithography light focusing optical systems with wavelengths below 300 nm, which uses low nano-density crystals to focus optical elements. The system uses a crystalline lens element with uniform crystal orientation as shown in Figure 4. The prior art cannot solve the problem of using a crystalline crystal element to operate a light lithographic printing beam. The present invention overcomes the problems of the prior art and provides a beneficial light lithographic printing element, which has beneficial optical characteristics and light lithographic printing characteristics. Contains the minimum birefringence and its hair embryo can be used to improve the collective production of lithographic printing using evacuated UV 绛 wavelength light lithography. The invention is summarized as follows: The embodiments of the present invention include fluorinated dance evacuated UV light stone with minimum birefringence. Printed lens. The lens preferentially contains a single calcium fluoride crystal. The calcium fluoride lens has an optical central axis surrounded by the periphery of the calcium fluoride lens, and the lens has different crystal orientations, which are oriented at the optical central axis and face the periphery. Another embodiment of the invention includes a fluoride crystal optical lens. The fluoride crystal optical lens includes a single fluoride crystal having a first optical lens surface and a second optical lens surface opposite to the first lens surface. The fluoride crystal has a gradual increase Concentration of crystal dislocation defect, which is caused by the first light

--i ---- (Please read the precautions on the back before filling this page) Order 518425 A7 B7 V. Description of the invention (3) The surface of the lens increases to the surface of the second optical lens. Another embodiment of the present invention includes a calcium fluoride crystal optical element to operate at a transmission wavelength λ &lt; 200 nm. The calcium fluoride crystal optical element includes a calcium fluoride crystal having a first optical lens surface and a second optical lens surface to operate light of a wavelength λ. The crystal dislocation defect concentration of the calcium fluoride crystal increases from the surface of the second optical lens to the surface of the first optical lens. The first optical surface has a first surface substructure surface length per unit area in the range of 10s50cm / cm2. Second surface substructure surface length per unit area An embodiment of the present invention includes a fluoride crystal lens hair embryo, which is composed of a fluoride crystal with a central axis passing through a larger-sized D surface. The central axis and the larger D surface are surrounded by the periphery of the embryo. The central axis is aligned and aligned with the crystal orientation of the fluoride crystal. The fluoride crystal lens hair embryo has a change in crystal orientation, and its central axis expands and deviates from the central axis and toward the periphery of the hair embryo. Printed by the Consumer Cooperative of the Central Standards Bureau of the Ministry of Economic Affairs Another embodiment of the present invention includes a birefringence minimal fluoride crystal light lithographic printing wool embryo. The hair embryo was composed of a calcium fluoride crystal, and had an internal transmittance of 193 nm &gt; 99% / cm and a refractive index uniformity of 1 ppm. The calcium fluoride crystal has a set of multiple non-parallel crystal orientations and the hair embryo has a central axis, which is consistent with the calcium fluoride crystal orientation. The hair embryo has a crystal periphery and the crystal orientation changes. The angular deviation between the central axis and the known non-parallel crystal orientation has a relative position between the central axis and the periphery, and the distance from the central axis is correlated. The angular deviation preferentially increases as the distance from the central axis increases. "Another embodiment of the present invention includes a fluoride crystal optical element hair embryo. The optical element hair embryo is made of fluoride crystal and has a diameter. The first diameter of this paper is also applicable to China IIIF7C-NS) M specification (-a97 公 酱) 518425 A7 ----- —_B7 V. Description of the invention (Life) Planar surface, second diameter plane surface, and the crystal thickness defined by the first and second surfaces ^. The concentration of the hairpin lens crystal dislocation defect is determined by the second Surface to surface increase. The second surface has a second surface substructure surface length per unit area and the first surface has a first surface substructure surface length per unit area, where FS> SS. Brief description of the drawings : The first figure (Figure 1) shows an embodiment of the process of the light lithographic printing system of the present invention. / The first figure to the second figure (Figure 2-2H) shows the embodiment of the light lithographic printing system / processing process of the present invention. Sectional views. / Second to third drawings (; (Figs. 3 to 3G) show sectional views of the embodiment of the light lithographic printing system / processing process of the present invention.-The fourth, ,,, and other members are shown.) Has uniform crystalline fingers A cross-sectional view of the 7G element of the gas crystal lens, whose light passes through the outside of the lens and has a light path that is not parallel to &lt; 111>. Fifth to fifth figures A (Figure 5-⑷ shows the present invention The sectional view of the example. The sixth figure (Figure 6) shows that the present invention contains the crystal orientation of <U1> crystallized calcium crystals, and the small circle indicates Ca. Printed by the Consumer Cooperative of the Central Standards Bureau of the Ministry of Economic Affairs Figure 7 (Figure 7) shows a cross-sectional view of an embodiment of the present invention, which contains increasing crystal dislocation defect concentration. Figure 8 (Figure 8) shows a cross-sectional view of an embodiment of the present invention, which contains increasing crystal dislocations. Defect concentration. The ninth to ninth graphs A (Figures 9-9A) show that the broken paper of the embodiment of the present invention is also applicable to the Chinese National Standard (CNS) A4 specification (210X297 mm) 518425 A7 __— —_____ B7 Explanation of the invention (f) 6 The printed surface of the Consumer Cooperatives of the Central Bureau of Standards of the Ministry of Economic Affairs. The tenth figure (Figure 10) shows the sectional view of the embodiment of the present invention. The eleventh figure (Figure 11) is calcium fluoride Optical micrograph of crystal surface. Figure 12 (Figure 12) is An optical micrograph of the surface of a calcium crystal. The thirteenth figure (Figure 13) shows an embodiment of the present invention. Description of the numerical symbols of the elements of the drawings: lens 50, 50 '; vacuum ultraviolet microlithography lithography system / processing private 51 Fluoride crystals 52, 52 '; Optical central axis 54; Lens perimeter 56; Crystals point 57, 58; Optical central axis 60; Curved optical surfaces 62, 64, 66; Flat optical surfaces 68; Ray path 72; Crystals Path 74; lens 76; fluoride crystal 78; lens surface 80; lens surface 80, 82; increasing concentration direction 84; crystal dislocation defect 86; lens hair embryo 100; fluoride crystal 102; central axis 104; Surface 106; hair embryo perimeter 108; crystal orientation 110; optical central axis 111; crystal orientation 112; surfaces 113, 114; orientation change 158. Detailed description: The present invention includes a fluoride crystal with minimal birefringence, a vaporized ultraviolet light lithography lens, which is composed of a fluoride crystal. As shown in Figures 丨, 2 and 3, the fluoride crystal vaporized ultraviolet light lithographic printing lens is used in the vaporized ultraviolet low light lithographic printing system / process 51, which preferentially uses the vaporized ultraviolet light wavelength <200 nm. Fluoride crystal lens elements are used in low-gloss lithographic printing systems, which include the optical elements that make up the lighting system, preferably a light source (preferably an excimer laser), and a projection system. Fluoride crystal light lithographic printing lens 50. Fluoride crystal 52. This paper size applies Chinese National Standard (CNS) A4 specification (210X297). -------.----- (Please read first (Notes on the back then fill out this page)

, 1T f 518425 A7 V'invention note (^), preferentially scale-crystal. As shown in Fig. 5, the fluoride crystal optical lens has an optical central axis 54 surrounded by a periphery 56 of the fluoride crystal lens. The fluoride lens has some changes in crystal orientation, which are offset from the optical center axis and directed toward the periphery 56. As shown in Fig. 5a, the crystal orientation 57 is offset from the optical center axis by 60 and expanded toward the periphery 56. In comparison with the change in crystal orientation, the lens 50 of FIG. 4 is composed of a fluoride crystal 52 ′ having a uniform junction d and d, which is parallel and oriented toward the central axis throughout the crystal. The fluoride crystal 52 has The smallest uniform concentration. The smallest dislocation defect. ^ The lens 50 is preferably composed of a calcium fluoride crystal 52. The internal transmittance of the calcium fluoride crystal is preferably 99% / cm. Figure 6 shows that the fluoride crystal has vaporized calcium crystal orientation 57. The crystal orientation is perpendicular to the relative calcium fluoride orientation plane. The fluoride crystal light lithographic lens 50 preferably has a first curved optical surface 62 and a second curved optical surface 64 to manipulate the light lithographic printing light, and preferably the light lithographic printing light ^ &lt; 2001111. The fluoride crystal light lithographic lens 50 preferably has a curved optical surface 66 and a planar optical surface 68 in another priority. Printed by the Consumers' Cooperative of the Central Standards Bureau of the Ministry of Economic Affairs. Priority crystallization points to a change of 58 in the range of 2 to 15 degrees, preferably 3 to 12 degrees, and most preferably 5 to 10 degrees. As shown in Fig. 5a, the crystal orientation changes from the optical central axis 54 to 60 and to the lens periphery 56. Preferentially, the crystal orientation &lt; 9 gradually increases from the central axis, so that θκβκβκθγ05 &lt; 06 &lt; 0 7 ·· &lt; 0 n. Fluoride crystal light lithographic printing lens 50 has non-parallel light path 72 and fluoride crystal 52 has non-parallel crystal path 74. Aligned to the size of this paper. Applicable to China National Standard (CNS) A4 specification (210 × 297 mm) 518425 A7 ---__ B7 V. Description of the invention (q) Mirror first line milk. The μ-direction crystal is briefly explained by the light path 72, and the lens 50 is designed to operate this path. The lens 50 and the crystal path 74 are preferentially converged or divergent. / Receipt from the date of delivery-The chemistry of crystals is well understood, which consists of mono-fluoride crystals. The fluoride crystal purchase has a first optical lens surface 80 and a second optical lens surface separated and supplemented. The fluoride crystal has a crystal dislocation with an increasing concentration of 84, which is gradually increased by the second optical lens surface 80. As shown in Fig. 7-8, the concentration of the dislocation defect is an increasing concentration as shown by arrow 84, and the concentration of the dislocation defect 86 increases preferentially from the second surface to the first surface 80. In prior implementation, the first optical lens surface is the curved lens surface, and the second optical transmission surface is the curved transmission surface. In another embodiment, the first optical lens surface decomposes the optical surface. In another embodiment, the second optical lens surface is a flat optical surface. The lens 76 preferably has an optical central axis 54 aligned in a local direction. In the priority implementation, the mono-fluoride rhenium 78 is fluorine, and the internal transmittance at 3nm is greater than 99% / cm. Printed by the Consumer Cooperatives of the Central Standards Bureau of the Ministry of Economic Affairs ---, ----- (Please read the precautions on the back before filling out this page) The present invention further includes a calcium fluoride crystal optical element to operate the transmission wavelength A &lt; 200nm . The optical element 76 having a wavelength of less than 200 nm is composed of a fluorinated feed crystal 78. The calcium fluoride crystal has a first optical surface 80 and a second optical surface 82 to operate at a lambda wavelength. The dislocation defect 86 concentration 84 of the calcium fluoride crystal increases from the second optical surface to the first optical surface. The first optical surface substructure has a surface length in the range of 10 to 50 cm / cm2 per unit area. The second optical surface substructure has a surface length &lt; 10 cm / cm2 per unit area. Element 76 has a larger dimension D. Priority D is greater than 100mm, more preferentially -150mm, and more preferably this paper size applies Chinese National Standard (CNS) A4 specification (210X297 mm) 518425 Α7 B7 5. Description of the invention (?) Employees' Cooperatives, Central Bureau of Standards, Ministry of Economic Affairs Printed -250mm, more preferentially -250mm, and most preferentially 2300mm. In a preferred embodiment, the first optical lens surface is a curved lens surface. In the preferred embodiment, the surface of the second optical lens is a curved lens surface. In the preferred embodiment, the central wavelength of λ is about 193 nm and the internal transmittance of the calcium fluoride crystal at I93 nm is> 99% / cm. In another embodiment, λ is located at 157 nm and the internal transmittance of the crystal is about 99% / cm. Preferably, the crystal orientation change of the calcium fluoride crystal of the optical element 76 will be expanded and deviated from the optical central axis. The change is preferably at least two degrees and more preferably 5 degrees. The invention further includes a fluoride crystal lens hair embryo. The fluoride lens lens blank 100 is composed of a fluoride crystal 102. The fluoride crystal 102 has a central axis 104 through a larger-sized D surface 106. The central axis 104 and the surface 106 are surrounded by the periphery of the hair embryo 108. The central axis 104 is aligned and aligned with the crystal 110. The fluoride crystal hair embryo 100 has a change 158 in the crystal orientation 112, which expands and deviates from the central axis 104 and faces the hair embryo 108. The 100% crystal orientation of the calcium fluoride lens hair embryos is preferentially 110% of the calcium fluoride lens orientation. The 193 nm internal transmittance of the calcium fluoride crystal 102 is preferably 99 Vcm. The larger dimension D of the calcium fluoride lens blank 100 is preferably glOOmm, more preferably -15mm, more preferably -250mm, more preferably -250mm, and most preferably 2300mm. The crystal orientation 112 changes 158 preferentially in the range of 2 to 15 degrees, more preferably in the range of 3 to 12 degrees, and most preferably in the range of 5 to 10 degrees. Calcium fluoride lens lens embryos vary 158 from the central axis 104 by at least 3 degrees, preferably -5 degrees. As shown in FIG. 9a, the hair embryo 100 (shown as a dashed line inside the hair embryo) formed as an optical element lens 76, 50 preferentially has a second surface 114 with respect to the fluoride crystal surface 106, with a crystal dislocation defect 86 concentration. Order by (Please read the notes on the back before filling this page)

This paper size is in accordance with Chinese National Standard (CNS) A4 (210 × 297 mm) (I 518425 A7 B7 10) Printed by the Consumer Cooperatives of the Central Standards Bureau of the Ministry of Economic Affairs 5. Description of the invention ((|) Second surface 114 to surface 106 Incrementally, as shown in FIG. 10, the optical lens blank 100 has a second surface having a second surface substructure boundary length per unit area SS and a surface area 106 having a larger size surface substructure boundary length per unit area is FS, where FS &gt; SS. Preferentially the length of the second surface substructure boundary length per unit area SS &lt; 10cm / cm2, and more preferably FS in the range of 10 to 50cm / cm2. Figure 11-12 shows the acid etched Calcium fluoride optical lens surface substructure boundary. These micrographs are fluorinated | bow surface after 15 minutes of engraving with 0.1N nitric acid. Figure 12 uses quantitative optical microscope analysis to measure the characteristics of the substructure boundary. Including the substructure boundary length per unit area. In Figure 12, the surface of the calcium fluoride optical hair embryo has a substructure boundary length per unit area of 15cm / cm2 and the average diameter of the substructure is about 丨 · 8_. The present invention further includes a birefringence minimum fluoride crystal light lithographic printing lens hair embryo. The optical element hair embryo is composed of a calcium fluoride crystal, and its internal transmission at 193 nm &gt; 99% / cm. As shown in FIG. 13, The calcium fluoride hair embryo 100 has a set of multiple non-parallel crystal orientations. The hair embryo 100 has an optical central axis 104 which is consistent with the local fluoride crystal orientation. The hair embryo has a change in crystal orientation 158, of which The angular deviation between the central axis 104 and the non-parallel crystal orientation at a known position is related to the relative distance between the known position and the central axis 104. At the known position, the central axis 104 and the surrounding 108 are related. There is a relative distance between them. As shown in FIGS. 13, 9 and 9a, the hair embryo 100 preferentially has a first surface 106 and a second surface 114 of dislocation defect ribs, the dislocation defects increasing from the second surface 114 to the first surface 106. Preferentially, the first and second surfaces are perpendicular to the central axis, and the shape of the blank 100 is preferentially a cylindrical dish blank of an appropriate size, which is a preform that will form and shape the optical element. Preferred blank 1 〇 (? This paper is applicable National Standard (CNS) A4 Specification (210X297 Public Director) (of ------- i ---------- order ------ · (Please read the notes on the back before filling (This page) 518425 A7 _______ V. Description of the invention (10) It has a first surface 106 and a second surface Π3, wherein the first surface of the second surface 114 has a substructure boundary length per unit area (indicated by SS) &lt; 1 〇 cm / cm2 and the second surface substructure boundary length of the first surface 106 per unit area (expressed as FS) ^ 10cm / cm2. The first surface substructure boundary length is preferably in the range of 10 to 50 cm / cm2 per unit area. The invention further includes a hair crystal of a fluoride crystal optical element. The hair embryo is preferably composed of a single fluoride crystal and most preferably a calcium fluoride crystal. The optical element blank 100 has a diameter D, a first diameter plane surface 106, a second diameter plane surface 114, and a crystal thickness TH between the first and second surfaces. The hair embryo 100 has a concentration material of crystal dislocation defect continuum, which increases from the second surface 114 to the first surface 106, and the second surface 114 has the second surface substructure boundary length per unit area and the first surface 1 〇6 has a first surface substructure boundary length per unit area, where FS &gt; SS. Preferably, SS is less than 10 cm / cm2. Preferably, the FS is in the range of 10 to 50 cm / cm2. Those skilled in the art can make various changes and modifications to the present invention, but it will not depart from the spirit and scope of the present invention. Therefore, the scope of the following patent applications will cover various changes and modifications of the present invention. Printed by the Staff Consumer Cooperative of the Central Bureau of Standards, Ministry of Economic Affairs

-: ---- (Please read the notes on the back before filling this page} Order # 1. (I

Claims (1)

Scope of patent application Printed by the Consumer Cooperative of the Central Standards Bureau of the Ministry of Economic Affairs ^ A birefringent minimal fluorine-poured UV light lithograph &quot; Hai lens is composed of It crystal, a fluoride crystal lens is surrounded by an optical calcium fluoride lens, fluorine Crystal lens in: crystal = edge optics &quot; preferred and lying fluoride crystal lens, please contact the lens of the professional group 1 item, in which the fluoride crystal is 1 ^ ^ according to the scope of the patent application of the lens, in which the fluoride crystal The light lithographic P brush lens has an -f-curved optical surface and a second, curved optical surface. 4. The lens according to item 1 of the patent application scope, wherein the fluoride crystal light lithographic printing lens has an f-curved optical surface and a planar optical surface. 5. The lens according to item 丨 of the patent application range, wherein the crystal orientation changes within the range of ^ to 15 degrees. 6. According to the towel, please make up for the 帛 1 slave lens. The change in the shooting direction M is within the range of 3 to 12 degrees. 7. The lens according to item 1 of the scope of patent application, wherein the crystal orientation changes within the range of 5 to 10 degrees. &amp; The lens according to item 1 of the scope of patent application, wherein the lens has a group of multiple light paths and the fluoride crystal includes a group of multiple crystal paths aligned with the light path of the lens. 9. · A fluoride crystal optical lens, which is composed of a single fluoride crystal, and has a first optical lens surface and a separate second optical lens surface, and the second optical lens surface is opposite to the first optical lens On the surface, the fluoride crystal has an increasing dislocation defect concentration, and its second light surface paper size is in accordance with China National Standards (CNS) 8.4 (21 × 297 mm). 518425 'A 8 B8 C8 D8 3 11 VI. Scope of Patent Application 6. The surface of the lens of the printed lens of the Consumer Cooperative of the Central Bureau of Standards of the Ministry of Economic Affairs is increasing from the surface of the first optical lens.丄 〇. The lens according to item 9 of the scope of the patent application, wherein the surface of the first optical lens is a curved lens surface and the surface of the second optical lens is a curved lens surface. 11. The lens according to item 9 of the scope of patent application, wherein the surface of the first optical lens is a flat optical surface. 12_ The lens according to item 9 of the scope of patent application, wherein the surface of the second optical lens is a flat optical surface. 13. A lens according to item 9 of the patent application, wherein the lens has an optical center axis aligned in a local direction. 14. The lens according to item 9 of the scope of patent application, wherein the fluoride crystal is a fluoride. 15. The lens according to item 3 of the patent application scope, wherein the internal transmittance of the calcium fluoride crystal i93 nm is> 99% / cm. 16 · —A calcium fluoride crystal optical element, which operates as a transmission wavelength λ &lt; 200 =, and the element includes a simple fluorine crystal, a financial surface and a second optical lens surface to operate λ, the calcium fluoride The dislocation defect concentration of the crystal increases from the second optical surface to the first optical surface. The first optical surface has a subsurface boundary length of the first surface in the range of 10 to 505 / cm2 per unit area and the second optical surface. Has a second surface substructure boundary length &lt; 1 Ocm / cm2 per unit area. 17. An optical element according to item 16 of the scope of patent application, wherein the element has a larger dimension D, where D ^ 100mm. 〃 ^ 18. The optical element according to item 16 of the scope of patent application has a large size D, of which D—. Every piece has a car parent ------ 1 ---- (Please read the precautions on the back before filling in this page) Order — k-core Zhangyiyihan CNS) (210χguidance) 518425 8 8 88 ABCD 14 VI. Application scope of patent 19. The optical element according to item 16 of the scope of application for patent, where the element has a larger size D, of which D-200mm. 20. The optical element according to item 16 of the scope of patent application, wherein the element has a larger dimension D, of which Dg is 250 mm. ^ 21. The optical element according to item 16 of the scope of patent application, wherein the element has a larger size D, of which D $ 300min. 22. The optical element according to item 16 of the scope of patent application, wherein the -optical surface is a curved lens surface. 23. The optical element according to item 16 of the application, wherein the second optical surface is a curved lens surface. 24. The optical element according to item 16 of the scope of patent application, wherein the wavelength; the center is located at 193 nm and the 193 nm internal transmittance of the fluorinated # 5 crystal is> 99% / cm. 25. The optical element according to item 16 of the patent application, wherein the center of the wavelength λ is 157 nm and the internal transmittance of the calcium fluoride crystal at 157 nm &gt; 99% / cm. · 26. The optical element according to item 17 of the scope of patent application, wherein the crystal orientation of the fluorinated feed crystal is changed away from and expanded from the optical axis. 27. An optical element according to item 26 of the patent application, wherein the change is at least 3 degrees. 28. The optical element according to item 26 of the scope of patent application, where the change is at least 5 degrees printed by the Consumer Cooperatives of the Central Standards Bureau of the Ministry of Economic Affairs (please read the precautions on the back before filling out this page). 29 · —A kind of fluoride crystal lens hair embryo, the lens hair embryo is composed of calcium fluoride crystal, which has a central axis passing through a larger size D surface, the axis and the larger size D surface are surrounded by the periphery of the hair embryo, This axis is aligned with and consistent with the crystal orientation of the fluoride crystal. The crystal orientation of the hair crystal of the fluoride crystal lens has changes. The wood and paper dimensions are applicable to the Chinese National Standard (CNS) A4 specification (210X297 mm). 518425 Patent application scope A8 B8 C8 D8 5 The Consumer Cooperative of the Central Bureau of Standards of the Ministry of Economic Affairs prints out and deviates from the central axis and towards the periphery of the blank. Lens germ of patent range _ item, among which fluoride crystal please use the lens germ of item 29 of the patent range, where larger size D: == r29 item-where the crystal orientation changes 33. According to the lens of the scope of application patent item 29 Hair germ, in which the hair germ has the first body 34. According to the application, the scope of the patent, the lens hair germ in which the hair germ has a first surface, the second wire extracts a large-sized surface, and the second surface has a second surface substructure. Boundary length per unit bay and larger-sized surfaces have larger-sized surfaces. Substructure boundary length per unit FS &gt; SS. 、,,, τ35 · The lens blank according to item 34 of the patent application scope, among which ss &lt; icm / cm2 ° 36. The lens blank according to item 34 of the patent application scope, where ⑺ is between cm and cm / cm2 Within range. 37 ·-a kind of birefringence minimum fluoride crystal light lithographic printing lens hair embryo, the hair embryo is composed of fluoride # 5 crystal, its internal transmission at 193nm; &gt; 99% / cm and refractive index uniformity S lppm, And a group of multiple non-parallel crystal pointing hair embryos have a central axis, which is consistent with fluorinated crystals, the hair embryos have a crystalline periphery and the crystal orientation has a change, in which a Thai paper scale is applicable between China National Standard (CNS) A4 specification (210X297 mm) (Please read the precautions on the back before filling this page) Order --- 518425 VI. The central axis and non-parallel crystals at the known position in the scope of the patent application indicate the position and The central smoke distance is correlated. The angle deviation has been 38. The hair embryo according to item 37 of the scope of the patent application, wherein the hair embryo is on the surface, and the crystal has a dislocation defect concentration, which is defined by the second surface ^-mouth, the surface length of the secondary structure = bit area & lt 10- and the first surface have a first-surface substructure boundary length per unit area of -10cm / cnl2. 40. The hair germ according to item 37 of the patent application scope, wherein the hair germ has a first surface and a first surface, the first and second surfaces are perpendicular to the central axis, and the second surface has a second surface read boundary length per unit The area <and the -surface has a -surface substructure boundary length per unit area in the range of ι0 to 50 cm / cm2. 41. A hair crystal of an optical element of a fluoride crystal, the hair embryo being composed of a fluoride crystal, the crystal having a seed, a first and a second planar surface, and a second diameter and a planar surface. The thickness of the crystal is defined. The hair embryo has a concentration of crystal dislocation defects, which increases from the second surface to the first surface and the employee consumer cooperative of the Central Standards Bureau of the Ministry of Economic Affairs. The system = the surface has a second surface. The secondary structure boundary length is ss per unit area. And the first surface has a first surface substructure boundary length per unit area where FS where FS> SS. '42. Lens blanks according to item 41 of the scope of patent application, where ss &lt; 10 cm / cm2 〇43. Lens blanks according to item 41 of scope of patent application, where ^ is applicable to 1f7 countries Ladder standard (CNS) A4 specification (210X297) 518425 A8 B8 C8 D8 6. The scope of patent application is within 50cm / cm2. (Please read the precautions on the back before filling out this page) Printed by the Consumers' Cooperative of the Central Bureau of Standards of the Ministry of Economic Affairs The size of the paper is applicable to the Chinese National Standard (CNS) A4 (210 × 297 mm)