Patent Number: 063339617
Section: claims

1. A reflection mask for use in microlithography, the reflection mask comprising: a multilayer mirror that reflects incident electromagnetic radiation of a prescribed wavelength; and  an absorptive layer superposed on the multilayer mirror, the absorptive layer defining elements of a pattern defined by the mask, wherein the multilayer mirror has a thickness period, through a thickness dimension of the multilayer mirror, that varies through the thickness dimension.  providing a reflection mask as recited in claim 1;  illuminating the reflection mask with the illumination light; and  passing the reflected illumination light through an imaging-optical system to as to form an image of the pattern on the substrate.  an illumination-optical system situated and configured to irradiate electromagnetic radiation from a source onto a reflection mask, the reflection mask defining a pattern to be projected onto a substrate;  an imaging-optical system situated and configured to direct portions of the electromagnetic radiation reflected from the reflection mask to the substrate so as to form an image of the pattern on the substrate; and  the reflection mask comprising a multilayer mirror that reflects a prescribed wavelength of the electromagnetic radiation and an absorber layer, superposed on the multilayer mirror, that absorbs the electromagnetic radiation and defines elements of the pattern, the multilayer mirror having a thickness period, through a thickness dimension of the multilayer mirror, that varies through the thickness dimension.  the electromagnetic radiation comprises soft X-rays; and  the multilayer mirror of the reflection mask is reflective to the soft X-rays. 2. The reflection mask of claim 1, wherein the electromagnetic radiation comprises soft-X-rays. 3. The reflection mask of claim 1, wherein the multilayer mirror is formed by laminating multiple blocks of multilayer, each block having a different thickness period. 4. The reflection mask of claim 3, wherein one layer of each multilayer includes silicon, and another layer of each multilayer includes molybdenum. 5. The reflection mask of claim 1, wherein the multilayer mirror is formed by laminating multiple multilayers superposedly such that the multilayer mirror has a thickness period that varies progressively with distance through a thickness dimension of the multilayer. 6. The reflection mask of claim 5, wherein one layer of each multilayer includes silicon, and another layer of each multilayer includes molybdenum. 7. In a method for performing microlithography of a pattern, defined by a reflection mask, onto a substrate, a method for reducing adverse effects on linewidth of the pattern, as transferred to the substrate, caused by a non-uniformity of reflection of illumination light from the reflection mask, the method comprising: 8. A microlithography apparatus, comprising: 9. The apparatus of claim 8, wherein: 10. In a method for manufacturing an integrated circuit, a microlithography step in which a circuit pattern, defined on a mask, is transferred to a wafer to form the circuit pattern on the wafer, the microlithography step being performed using a reflection mask comprising a multilayer mirror that reflects a prescribed wavelength of electromagnetic radiation and an absorber layer, superposed on the multilayer mirror, that absorbs the electromagnetic radiation and defines elements of the pattern, the multilayer mirror having a thickness period, through a thickness dimension of the multilayer mirror, that varies through the thickness dimension. 11. The method of claim 10, wherein the electromagnetic radiation comprises soft X-rays.