Patent Number: 054147468
Section: claims

1. An X-ray exposure mask for exposing a sample by means of a 1:1 proximity printing method with an incident X-ray from an X-ray source comprising: an X-ray transmission layer for transmitting an X-ray being incident On the X-ray exposure mask; and  an X-ray absorption layer for absorbing said X-ray being incident on the X-ray exposure mask, said X-ray absorption layer formed on said X-ray transmission layer and being composed of a single material and being patterned to have a plurality of patterns with substantially right-angled edges and respective plane projection areas and thicknesses, the thickness of the respective patterns being varied in accordance with the plane projection area of the respective patterns and larger where the plane projection area is larger.  wherein n is a refractive index of said X-ray absorption layer, .lambda. is a peak power wavelength of the X-ray that is incident on the X-ray mask measured in nano meters, and .lambda. is a linear absorption coefficient of said X-ray absorption layer measured in a reciprocal of nano meters.  wherein G is a distance between a mask and said sample, and .lambda. is a peak power wavelength of said incident X-ray measured in micro meters.  wherein G is a distance between a mask and said sample, and .lambda. is a peak power wavelength of said incident X-ray measured in micro meters.  wherein G is a distance between a mask and said sample, and .lambda. is a peak wavelength of said incident X-ray measured in micro meters.  an X-ray transmission layer for transmitting the incident X-ray; and  an X-ray absorption layer for absorbing said incident X-ray, said absorption layer comprising a single material formed on said X-ray transmission layer and patterned to have at least one first pattern including a first X-ray absorber and a second X-ray absorber arranged apart from each other, said first and second X-ray absorbers having an inner portion for defining a window and an outer portion being connected with said inner portions, respectively, said outer portion having a first plane projection area and a first thickness and said inner portion having a second plane projection area smaller than said first plane projection area and a second thickness less than said first thickness; a second pattern including a third X-ray absorber, a fourth X-ray absorber and at least one fifth X-ray absorber placed between said third and fourth X-ray absorbers with an interval, said third and fourth X-ray absorbers having an inner portion for defining a window in co-operation with said fifth X-ray absorber and an outer portion being connected with said inner portion, respectively, said outer portions of said third and fourth X-ray absorbers having said first thickness and said inner portions of said third and fourth X-ray absorbers and said at least one fifth x-ray absorber having said second thickness; and a third pattern composed of a sixth X-ray absorber extended in a striped geometry, a central portion of said sixth X-ray absorber having said first thickness and side portions along the periphery of said sixth X-ray absorber having said second thickness.  wherein G is a distance between a mask and an exposure sample, and .lambda. is a peak power wavelength of said incident X-ray measured in micro meters.  wherein n is a refractive index of said X-ray absorption layer, .lambda. is a peak power wavelength of said incident X-ray measured in nano meters, and .mu. is a linear absorption coefficient of said X-ray absorption layer measured in a reciprocal of nano meters.  forming an X-ray transmission layer on a substrate;  forming an X-ray absorption layer composed of a single material on said X-ray transmission layer;  forming a first etching mask layer including patterns on said X-ray absorption layer;  forming a channel on said X-ray absorption layer by unisotropic etching process using said first etching mask layer;  forming a second etching mask layer by removing a designated amount of said first etching mask layer from its side face and its upper face by isotopic etching of said first etching mask layer; and  forming an X-ray absorption layer composed of specific patterns, said X-ray absorption layer having an edge part, the thickness of which is smaller than the thickness of a region below said second etching mask layer, by using said second etching mask layer as a mask and by unisotropic etching process for removing said X-ray absorption layer. 2. An X-ray exposure mask as claimed in claim 1, wherein said X-ray absorption layer has at least one first pattern having a first plane projection area and a first thickness and at least one second pattern having a second plane projection area and a second thickness, said second plane projection area being smaller than said first plane projection area and said second thickness being less than said first thickness. 3. An X-ray exposure mask as claimed in claim 2, wherein said second thickness, designated t measured in nano meters, of said second region satisfies that EQU 30&lt;.vertline.360 (1-n) t/.lambda..vertline.&lt;120 and EQU 1&lt;1/exp (-.mu.t)&lt;4, 4. An X-ray exposure mask as claimed in claim 3, wherein a plurality of said second patterns are formed and arranged at regular intervals. 5. An X-ray exposure mask as claimed in claim 2, wherein said first pattern further has a part with said second thickness. 6. An X-ray exposure mask as claimed in claim 5, wherein a width designated L of said second pattern satisfies that EQU L.ltoreq.1.2 (G.lambda.).sup.1/2, 7. An X-ray exposure mask as claimed in claim 2, wherein said X-ray absorption layer is patterned to have a window and a first X-ray absorber and a second X-ray absorber for defining said window, and each of said first X-ray absorber and said second X-ray absorber has said second region with said second thickness at an inner side whereby said window is defined, and said first region with said first thickness outside of said second region. 8. An X-ray exposure mask as claimed in claim 7, wherein a width designated L of said second region satisfies that EQU L.ltoreq.1.2 (G.lambda.).sup.178 , 9. An X-ray exposure mask as claimed in claim 8, wherein said first X-ray absorber and said second X-ray absorber are extended in parallel with each other. 10. An X-ray exposure mask as claimed in claim 2, wherein a center portion of said X-ray absorption layer has said first thickness and peripheral portion of said X-ray absorption layer has said second thickness. 11. An X-ray exposure mask as claimed in claim 10, wherein a width designated L of said peripheral portion satisfies that EQU L.ltoreq.1.2 (G.lambda.).sup.1/2, 12. An X-ray exposure mask as claimed in claim 2, wherein said X-ray absorption layer is structured such that among said incident X-rays, X-rays passed through said X-ray absorption layer interfere with X-rays passed through said X-ray transmission layer and are diffracted to form an X-ray intensity profile in accordance with said pattern of said X-ray absorption layer. 13. An X-ray exposure mask as claimed in claim 1, wherein said single material substantially comprises tantalum. 14. An X-ray exposure mask for exposing a sample by means of a proximity printing method with an incident X-ray from an X-ray source comprising: 15. An X-ray exposure mask as claimed in claim 14, wherein width of said inner portions of said first and second X-ray absorbers, said inner portions of said third and fourth X-ray absorbers and said side portions of said sixth X-ray absorber does not exceed EQU 1.2(G.lambda.).sup.1/2, 16. An X-ray exposure mask as claimed in claim 14, wherein a plurality of said fifth X-ray absorbers are arranged at regular intervals. 17. An X-ray exposure mask as claimed in claim 14, wherein said second thickness, designated t measured in nano meters, satisfies that EQU 30&lt;.vertline.360 (1-n) t/.lambda..vertline.&lt;120 and EQU 1&lt;1/exp (-.mu.t)&lt;4, 18. A process for fabricating an X-ray exposure mask comprising the steps of: