Patent Number: 06160867&
Section: description

DETAILED DESCRIPTION An X-ray-reflecting mirror according to a preferred embodiment of the invention comprises, on a suitable rigid substrate, layers of a first material and layers of a second material in alternating sequence in superposed fashion. Most preferably, each layer of the first material consists essentially of molybdenum (Mo), and each layer of the second material consists essentially of silicon (Si) as the principal constituent, with a dopant (preferably boron (B)) diffused into the silicon. By adjusting the dopant concentration in the silicon, the internal stress of the multi-layer reflective mirror can be controlled and minimized, compared to conventional multi-layer X-ray-reflecting mirrors, without having to rely on altering fabrication conditions and without reducing the reflectance of the mirror. The manner in which internal stress is understood to be controlled is as follows. When atoms diffuse into a crystalline substance, such diffusion can be of two types: "replacement diffusion" in which the diffusing atoms replace atoms of the substance at any of various lattice-point positions of the crystal lattice of the substance; and "penetration diffusion" in which the diffusing atoms penetrate between crystal-lattice positions of the substance. The type of substance into which the diffusion is occurring determines which will occur. For example, boron and certain other elements undergo replacement diffusion in silicon. The radius of a silicon atom is 1.17 .ANG., while the radius of a boron atom, as a representative dopant atom, is 0.88 .ANG.. Gilifalco, Atomic Diffusion in Crystals, Kyoritsu Publishing Co., 1980. I.e., the radius of a boron atom is only 75% the radius of a silicon atom; if a boron atom is inserted into a lattice point in a silicon crystal, the surrounding silicon atoms experience a tensile stress. As a result, the silicon crystal in general acquires a tensile stress. Tensile stress generated in this fashion increases as the boron concentration in the silicon is increased. For example, if 10.sup.20 atoms/cm.sup.3 of boron (approximately 0.1 atomic %) are introduced into monocrystalline Si, a tensile stress of about 100 MPa can be generated in the crystal. In a Mo/Si multi-layer mirror structure made using a sputtering technique, the molybdenum layers and the silicon layers have a compression stress due to the "peening" effect discussed above. The degree of such internal stress throughout the Mo/Si multi-layer mirror structure is dependent upon the conditions under which the layers were formed; in general, such stress is in the range of several tens of MPa to several hundreds of MPa. A representative multi-layer mirror structure according to the invention is shown in FIG. 1. A rigid substrate preferably made of glass or, alternatively, synthetic quartz ((e.g., "Zerodur" made by Schott or "ULE" made by Corning), or SiC, is provided with a mirror-polished surface. The substrate thickness is not critical so long as it has sufficient mechanical rigidity, stiffness, or stability. For example, a silicon substrate can have a thickness of 0.5 mm. Greater precision may require greater thickness, e.g., a thickness of 1/2, 1/3, or 1/4 the diameter of the substrate. In one representative embodiment, a layer 2 of a first material, preferably consisting essentially of molybdenum (Mo) (Mo is especially preferred for .lambda.=13 nm), is applied to the mirror-polished surface. As an alternative to Mo, the first material can consist essentially of Rh, Ru, Re, W, Ta, Ni, Cr, or Al, or any of various alloys of these materials. A layer 3 of a second material is applied superposedly to the first layer 2. The second material consists essentially of silicon (Si), as a principal ingredient, and a dopant. The dopant is preferably boron, but carbon or phosphorus can be used alternatively as the dopant. As an alternative to starting with the layer 2 of the first material on the substrate surface, it is possible to start with the layer 3 of the second material. In any event, additional first and second layers 2, 3 are superposedly applied in alternating sequence until the desired number of layers of the resulting multi-layer mirror structure has been formed. The number of layers is preferably in the range of 30-100, and most preferably about 50. Each of the layers 2, 3 is typically applied using any of various sputtering techniques, in which the "peening" effect becomes manifest (the peening effect generates a compression stress in the resulting structure). As an alternative to sputtering, vacuum evaporation can be used. The dopant is introduced into each of the silicon layers 3 by replacement diffusion (replacement diffusion of, e.g. , boron into crystalline silicon generates a tensile stress in the resulting structure). The tensile stress effectively offsets the compression stress imparted by sputtering to produce a substantially lower net stress in the structure. The tensile stress of the silicon layers increases as the dopant concentration in such layers increases. As a result, the net internal stress (i.e., the sum of the compression stress and tensile stress) of the multi-layer structure can be readily controlled and manipulated simply by adjusting the dopant concentration. FIG. 2 is a representative plot illustrating how the net internal stress in a Mo/Si multi-layer mirror structure (in this example, made with alternating layers of molybdenum as the first material and B-doped silicon as the second material applied by sputtering) can be reduced to zero. In FIG. 2, the abscissa is boron concentration in the silicon layers and the ordinate is net internal stress of the structure. Each molybdenum layer has substantially the same compression stress because, preferably, each molybdenum layer has the same thickness and was preferably applied using the same technique (e.g., sputtering) under similar conditions. The internal stress of the silicon layers changes from compression stress to tensile stress as the boron concentration increases in the silicon layers. At point A in FIG. 2, the total compression stress of the molybdenum layers and the total tensile stress of the silicon layers are equal and thus cancel each other in the overall structure. Thus, the net internal stress throughout the multi-layer structure is zero. In a multi-layer mirror structure according to this invention, the dopant concentration in the silicon layers is preferably 1.times.10.sup.18 atoms/cm.sup.3 (equal to 0.002 atomic %) or higher so as to provide a substantial reduction of the compression internal stress of the structure. The concentration of dopant is preferably the same in all the silicon layers. The thickness of each layer of the first material is not necessarily equal to the thickness of each layer of the second material, but the thickness of each layer of the first material is preferably the same. In any event, when the product of the "internal stress" and the "layer thickness" for the layers of the first material is equal to such a product for the layers of the second material, the internal stress of the multi-layer structure is zero. Introduction of dopant into the silicon (e.g., doping the silicon with boron) causes a change in the complex refractive index of the silicon. According to conventional wisdom, such a change would be expected to produce a significant decline in reflectance. However, as exemplified in FIG. 3, the introduction of boron into the silicon layers of the multi-layer structure causes substantially no loss of reflectance. Specifically, FIG. 3 depicts a representative reflectance (when the incident X-ray has a zero angle of incidence) from a Mo/Si multi-layer mirror structure comprising 50 layer pairs. Each layer of the first material in the FIG. 3 example has a thickness of 2.2 nm and each layer of the second material has a thickness of 4.5 nm. In the case of normal incidence, the condition for high reflectance is 2d =.lambda.. The wavelength deviation .DELTA..lambda. from .lambda. at which maximal reflectance is obtained is determined from the deviation .DELTA.d of the thickness d of a layer according to the following: .DELTA..lambda./.lambda.=.DELTA.d/d =.DELTA.d(Si)/d(Si)=.DELTA.d(Mo)/d(Mo). .DELTA.d(Si) and .DELTA.d(Mo) can be determined from the magnitude of deviation of the wavelength at which maximum reflectance is obtained, and from the magnitude of the change of reflectance at the wavelength .lambda. that is tolerable. FIG. 3 depicts curves obtained in the following four examples: (a) a multi-layer structure in which the silicon layers contain no boron, (b) a multi-layer structure in which the silicon layers contain 0.1 atomic % boron, (c) a multi-layer layer structure in which the silicon layers contain 1.0 atomic % boron, and (d) a multi-layer structure in which the silicon layers contain 10 atomic % boron. Peak wavelengths and reflectances for each of these four examples are listed below. ______________________________________ Boron Concentration Peak Wavelength Reflectance ______________________________________ 0 at % 131.6 .ANG. 74.3% 0.1 at % 131.6 .ANG. 74.3% 1 at % 131.6 .ANG. 74.2% 10 at % 131.4 .ANG. 73.4% ______________________________________ Hence, introduction of boron (as a representative dopant) into the silicon layers of a multi-layer mirror structure according to the invention causes essentially no decline in reflectance. As an alternative to molybdenum as a first material, any of various other materials can be used such as Rh, Re, W, Ta, Ni, Cr, Al, and alloys of such materials. The invention will be better understood by reference to the following example embodiments, which are intended to merely illustrate the best mode now known for practicing the invention. The scope of the invention is not to be considered limited to these example embodiments. EXAMPLE EMBODIMENT 1 A multi-layer mirror structure according to this example embodiment was formed using an ion-beam sputtering technique. Specifically, for forming the layers of the first material and the layers of the second material, a molybdenum (Mo) sputtering target and a silicon (Si) sputtering target, respectively, were used. The Si target had a boron (B) concentration of 0.5 atomic %. The resulting multi-layer mirror structure was formed by alternately layering the Mo layers 2 and the B-diffused Si layers 3 onto a mirror-polished surface of a glass substrate 1 (FIG. 1). The period length of the multi-layer mirror structure was 6.7 nm (the thickness of each Mo layer was 4.5 nm and the thickness of each Si layer was 2.2 nm). Fifty pairs of layers were applied to the substrate. For comparison, a Mo target and a Si target containing no boron were used to make, using an ion-beam sputtering technique, a "control" multi-layer mirror structure having the same period length, layer thicknesses, and number of layers as the example embodiment. The net internal stresses of the example embodiment and of the control were calculated, using conventional methods, from measured substrate warping (bending) before and after the formation of the fifty pairs of layers. The calculations can be performed in at least two ways: (a) sum up all the Fresnel coefficients of each interlayer boundary as an interference effect; or (b) perform a matrix analysis as described in Born and Wolf, Principles of Optics, 5.sup.th edition, pp. 51-70, Pergamon Press, 1975, incorporated herein by reference. The net internal stress of the control was approximately 300 MPa of compression stress. The net internal stress of the example embodiment was approximately 10 MPa of tensile stress. This example embodiment exhibited reflectance behavior as profiled in FIG. 3. Thus, this example embodiment exhibited a substantial reduction of internal stress without a decline in reflectance. EXAMPLE EMBODIMENT 2 A multi-layer mirror structure according to this example embodiment was made using a high-frequency magnetron sputtering technique. To make each layer of the first material, a Mo sputtering target was used; to make each layer of the second material, a Si sputtering target having a boron (B) concentration of 0.4 atomic % was used. The Mo layers 2 and the B-doped Si layers 3 were alternately applied to a mirror-polished surface of a glass substrate 1 (FIG. 1). The period length was 6.7 nm (the thickness of each Mo layer was 4.5 nm and the thickness of each Si layer was 2.2 nm), and 50 pairs of layers were applied. As a control, an otherwise similar multi-layer mirror structure was formed using the same technique but in which the Si layers contained no boron. The control had the same periodic length, layer thicknesses, and number of layers as the example embodiment. The net internal stresses of each multi-layer mirror structure were calculated from measured warping (bending) of the substrate before and after the layers were applied. The net internal stress of the control was approximately 300 MPa of compression stress, and the net internal stress of the example embodiment was approximately 5 MPa of tensile stress. This example embodiment exhibited a reflectance profile as shown in FIG. 3. Thus, this example embodiment exhibited a substantially reduced net internal stress without a significant decline in reflectance. EXAMPLE EMBODIMENT 3 A multi-layer mirror structure according to this example embodiment was formed using an ion-beam sputtering technique. To make each layer of the first material, sputtering was performed using a Mo sputtering target. To make each layer of the second material, sputtering was performed using a compound sputtering target. The compound sputtering target comprised Si extending over a portion of a boron target surface, wherein the surface-area ratio of boron (B) to Si on the target surface was 1:5. The multi-layer mirror structure was formed by alternately layering Mo layers 2 and B-doped Si layers 3 on a mirror-polished surface of a glass substrate 1 (FIG. 1). The period length of the multi-layer mirror structure was 6.7 nm (the thickness of each molybdenum layer was 4.5 nm and the thickness of each silicon layer was 2.2 nm). Fifty pairs of layers were applied. For comparison, a "control" structure comprising alternating layers of Mo and Si (without any boron) was formed using the same sputtering technique. The control had the same period length, layer thicknesses and number of layers as the example embodiment. The net internal stresses of the example embodiment and of the control were determined from measurements of warping (bending) of the substrate before and after forming the layers on the substrate. The net internal stress of the control was approximately 300 MPa of compression stress, and the net internal stress of the example embodiment was approximately 10 MPa of tensile stress. This example embodiment exhibited a reflectance profile as shown in FIG. 3. Thus, this example embodiment exhibited a substantial reduction of net internal stress without a significant decline in reflectance. EXAMPLE EMBODIMENT 4 A multi-layer mirror structure according to this example embodiment was made using a high-frequency magnetron sputtering technique. To make each layer of the first material, sputtering using a Mo sputtering target was performed. To make each layer of the second material, sputtering using a compound sputtering target was performed. The compound sputtering target comprised a Si wafer extending over a portion of a boron (B) target surface, wherein the ratio of B-to-Si surface area on the target surface was 1:6. The multi-layer mirror structure was formed by alternately layering Mo layers 2 and B-doped Si layers 3 onto a mirror-polished surface of a glass substrate 1 (FIG. 1). The period length of this example embodiment was 6.7 nm (the thickness of each Mo layer was 4.5 nm, and the thickness of each Si layer was 2.2 nm). Fifty pairs of layers were formed. For comparison, a "control" structure was formed using the same sputtering technique, except that the Si layers contained no boron. The control had the same period length, layer thicknesses, and number of layers as the example embodiment. The net internal stresses of the control and of the example embodiment were calculated from measurements of warping (bending) of the substrate before and after application of the layers. The net internal stress of the control was approximately 300 MPa of compression stress, but the net internal stress of the example embodiment was approximately 5 MPa of tensile stress. This example embodiment exhibited a reflectance profile as shown in FIG. 3. Thus, this example embodiment exhibited a substantially reduced internal stress without a significant decline in reflectance. Each of the example embodiments exhibited a reduced net internal stress, compared to controls lacking dopant in the silicon layers, that was independent of the technique used to form the multi-layer mirror structure. The example embodiments also demonstrated that the net internal stress of a multi-layer mirror structure according to the present invention can be freely controlled by manipulating the concentration of dopant in the silicon layers. For example, an otherwise substantial net compression stress can be eliminated entirely or converted to a slight net tensile stress. This allows excellent control over warping of the structure due to excessive internal stress, with a consequent remarkable improvement in optical performance of the multi-layer mirror structure. Whereas the invention has been described in connection with a preferred embodiment and multiple example embodiments, it will be understood that the invention is not limited to those embodiments. On the contrary, the invention is intended to encompass all modifications, alternatives, and equivalents as may be encompassed within the spirit and scope of the invention as defined by the appended claims.