Patent Number: 050864432
Section: claims

1. A multiplayer mirror having signfiicant reflectivity at a signle chosen shorter wavelenght o incident x-radiation, while suppressing the reflectivity t a single chosen longer incident wavelenght, comprising in combination: a. a plurality of layers of a first high-Z material, each of said first high-Z material layers having a first thickness and being sapced apart from each other;  b. a plurality of layers of a first low-Z material, each of said first low-Z material layers having a second thickness, said low-Z material layers and said high-Z material layers being disposed such that a low-Z material material layer, such that the plurality of first high-Z material layers and the plurality of interspersed first low-Z material layers efficiently reflect the chosen wavelenght of incident x-radiation;  c. t least one second high-Z material layer having a third thickness and disposed such that said at leat one second high-Z material layer receives the incident x-radiation; and  d. at least one second low-Z material layer having a fourth thickness, said at least one second low-Z material layer disposed between said at least one second high-Z material layer and the one of said first high-Z material layers which is the first to receive the incident x-radiation, forming thereby at least one pair of antireflection layers such that said at least one layer pair is a wavetap for the chosen wavelenght of incident longer-wavelenght radiation for which the reflectivity thereof is to be suppressed. 2. The multilayer mirror as described in claim 1, wherein said at least one second hight 2- material layer and said at least one second low-2 material layer include two-layer pairs. 3. The multilayer mirror as described in claim 2, wherein said first high-Z material layer, said second high-Z material layer, said first low-Z material layer, second thickness, the third thickness, and the fourth thickness are optimized to maximize reflection of the chosen shorter wavelength of soft x-radiation, while suppressing reflection of the chosen longer wavelenght of radiation. 4. The multilayer mirror as described in claim 3, wherein said first high-Z material layer and said second high-Z material layer include metallic atoms, and wherein said first low-Z material layer and said second low-Z material layer include non-metallic atoms. 5. The multilayer mirror as described in claim 4, wherein said first high-Z material layer and said second high-Z material layer include molybdenum atoms, and wherein said first low-Z material layer and said second low-Z material layer include silicon atoms. 6. The multilayer mirror as described in claim 5, wherein the first thickness is about 31 .ANG. and the second thickness is about 70 .ANG., and wherein the third thickness is about 11 .ANG. and the fourth thickness is about 47 .ANG., whereby the reflectivity of 186 .ANG. radiation is maximized, while that at 304 .ANG. is suppressed. 7. The multilayer mirror as described in claim 5, wherein the first thickness is about 35 .ANG. and the second thickness is about 58 .ANG., and wherein the third thickness is about 11 .ANG. and the fourth thickness is about 45 .ANG., whereby the reflectivity of 170 .ANG. radiation is maximized, while that at 304 .ANG. is suppressed. 8. The multilayer mirror as described in claim 5, wherein the first thickness is about 28 .ANG. and the second thickness is about 42 .ANG., and wherein the third thickness is about 10 .ANG. and the fourth thickness is about 45 .ANG., whereby the reflectivity of 130 .ANG. radiation is maximized, while that at 304 .ANG. is suppressed.