A reflective mask includes a substrate, a reflective multilayer disposed on the substrate, a capping layer disposed on the reflective multilayer, and an absorber layer disposed on the capping layer. The absorber layer includes a base material made of one or more of a Cr based material, an Ir based material, a Pt based material, or Co based material, and further contains one or more additional elements selected from the group consisting of Si, B, Ge, Al, As, Sb, Te, Se and Bi.

An apparatus and a method for correctly measuring a phase of an extreme ultraviolet (EUV) mask and a method of fabricating an EUV mask including the method are described. The apparatus for measuring the phase of the EUV mask includes an EUV light source configured to generate and output EUV light, at least one mirror configured to reflect the EUV light as reflected EUV light incident on an EUV mask to be measured, a mask stage on which the EUV mask is arranged, a detector configured to receive the EUV light reflected from the EUV mask, to obtain a two-dimensional (2D) image, and to measure reflectivity and diffraction efficiency of the EUV mask, and a processor configured to determine a phase of the EUV mask by using the reflectivity and diffraction efficiency of the EUV mask.

An apparatus and a method for correctly measuring a phase of an extreme ultraviolet (EUV) mask and a method of fabricating an EUV mask including the method are described. The apparatus for measuring the phase of the EUV mask includes an EUV light source configured to generate and output EUV light, at least one mirror configured to reflect the EUV light as reflected EUV light incident on an EUV mask to be measured, a mask stage on which the EUV mask is arranged, a detector configured to receive the EUV light reflected from the EUV mask, to obtain a two-dimensional (2D) image, and to measure reflectivity and diffraction efficiency of the EUV mask, and a processor configured to determine a phase of the EUV mask by using the reflectivity and diffraction efficiency of the EUV mask.

A substrate with a conductive film for manufacturing a reflective mask which has a rear-surface conductive film with high mechanical strength and is capable of correcting positional deviation of the reflective mask from the rear surface side by a laser beam or the like. A substrate with a conductive film has a conductive film formed on one surface of a main surface of a mask blank substrate used for lithography, wherein the conductive film includes a transparent conductive layer provided on a substrate side and an upper layer provided on the transparent conductive layer, the conductive film has a transmittance of 10% or more for light of wavelength 532 nm, the upper layer is made of a material including tantalum (Ta) and boron (B), and the upper layer has a film thickness of 0.5 nm or more and less than 10 nm.

A substrate with a conductive film for manufacturing a reflective mask which has a rear-surface conductive film with high mechanical strength and is capable of correcting positional deviation of the reflective mask from the rear surface side by a laser beam or the like. A substrate with a conductive film has a conductive film formed on one surface of a main surface of a mask blank substrate used for lithography, wherein the conductive film includes a transparent conductive layer provided on a substrate side and an upper layer provided on the transparent conductive layer, the conductive film has a transmittance of 10% or more for light of wavelength 532 nm, the upper layer is made of a material including tantalum (Ta) and boron (B), and the upper layer has a film thickness of 0.5 nm or more and less than 10 nm.

The prevent disclosure provides a method for forming a reflective mask. In some embodiments, the method includes forming a carbon-containing layer over a substrate; forming a reflective multilayer over the carbon-containing layer; forming an absorption pattern over the reflective multilayer. In some embodiments, the method includes growing a light absorbing layer over a substrate; polishing the light absorbing layer; forming a reflective layer over the polished light absorbing layer; forming an absorption pattern over the reflective layer.

The prevent disclosure provides a method for forming a reflective mask. In some embodiments, the method includes forming a carbon-containing layer over a substrate; forming a reflective multilayer over the carbon-containing layer; forming an absorption pattern over the reflective multilayer. In some embodiments, the method includes growing a light absorbing layer over a substrate; polishing the light absorbing layer; forming a reflective layer over the polished light absorbing layer; forming an absorption pattern over the reflective layer.

A reflective mask blank includes, on/above a substrate in the following order from the substrate side a multilayer reflective film which reflects EUV light and an absorber film which absorbs EUV light. The absorber film is a tantalum-based material film containing a tantalum-based material. The absorber film provides a peak derived from the tantalum-based material in an X-ray diffraction pattern, the peak having a peak diffraction angle (2θ) of 36.8 degrees or more and a full width at half maximum of 1.5 degrees or more.

A reflective mask blank includes, on/above a substrate in the following order from the substrate side a multilayer reflective film which reflects EUV light and an absorber film which absorbs EUV light. The absorber film is a tantalum-based material film containing a tantalum-based material. The absorber film provides a peak derived from the tantalum-based material in an X-ray diffraction pattern, the peak having a peak diffraction angle (2θ) of 36.8 degrees or more and a full width at half maximum of 1.5 degrees or more.

A reflectivity and transmittance measuring device includes: an EUV light source for outputting EUV light with a wavelength ranging from 5 nm to 15 nm; a multilayer reflection zone plate having an EUV reflection multilayer film, which is a planar substrate, and a zone plate pattern; and an EUV lighting unit for creating EUV illumination light by obtaining 1.sup.st diffraction light reflected after radiating EUV light output from the EUV light source to the multilayer reflection zone plate.