Abstract: Systems and methods are used to modify a layer on a substrate that is used to form a pattern generator, so that light reflecting from the modified substrate has a trapezoidal or other custom profile. The layer is modified using various vapor deposition techniques in conjunction with moving or positioning the substrate a desired distance from a blocking device and/or at a desired rate or speed.

Abstract: A diffraction element can be used in a system employing very short wavelengths of light, for example light in the nanometer range (e.g., about 100 nm to about 300 nm). The diffraction element is formed using a substrate (or any optical element) having high transmission characteristics in this wavelength range. For example, calcium fluoride or barium fluoride can be used. A layer of amorphous isotropic material, such as silicon dioxide or silica, is deposited on the substrate and patterned to allow for diffraction.

Abstract: A method for reducing the scattered light emitted through an optical element is provided that protects adhesive used to hold the optical element in place from light induced deterioration. In one embodiment, the method includes applying a thin coating of an organoxy metallic compound to a region on an optical element where adhesive will be applied and exposing the organoxy metallic compound to ultra-violet light. Exposure to ultra-violet light converts the organoxy metallic compound to its corresponding metal oxide forming an optically inert, light absorbing coating that protects adhesive used to hold the optical element in place from light induced deterioration.

Abstract: A lithographic apparatus is provided in which exposure is carried out by projecting through an aqueous solution of alkali metal halide(s), the solution being in contact with the substrate to be exposed.

Abstract: Systems and methods are used to modify a layer on a substrate that is used to form a pattern generator, so that light reflecting from the modified substrate has a trapezoidal or other custom profile. The layer is modified using various vapor deposition techniques in conjunction with moving or positioning the substrate a desired distance from a blocking device and/or at a desired rate or speed.

Abstract: A beamsplitter includes a first fluoride prism and a second fluoride prism. A coating interface is between the first and second fluoride prisms, wherein an overall R(s)*T(p) function of the beamsplitter varies no more than ±2.74% in the range of 40-50 degrees of incidence.

Abstract: The present invention relates to an apparatus for polarizing an incident light beam. In embodiments, a tile wave plate assembly is provided. The tile wave plate includes a layered structure having a substrate plate and two layers of mosaic tiles. The layers of the apparatus are mechanically separated to form a controlled gap spacing. The mosaic tiles can be configured to form a pseudo or true zero order wave plate.

Abstract: A diffraction element can be used in a system employing very short wavelengths of light, for example light in the nanometer range (e.g., about 100 nm to about 300 nm). The diffraction element is formed using a substrate (or any optical element) having high transmission characteristics in this wavelength range. For example, calcium fluoride or barium fluoride can be used. A layer of amorphous isotropic material, such as silicon dioxide or silica, is deposited on the substrate and patterned to allow for diffraction.

Abstract: A diffraction element can be used in a system employing very short wavelengths of light, for example light in the nanometer range (e.g., about 100 nm to about 300 nm). The diffraction element is formed using a substrate (or any optical element) having high transmission characteristics in this wavelength range. For example, calcium fluoride or barium fluoride can be used. A layer of amorphous isotropic material, such as silicon dioxide or silica, is deposited on the substrate and patterned to allow for diffraction.

Abstract: A beamsplitter includes a first fluoride prism and a second fluoride prism. A coating interface is between the first and second fluoride prisms, wherein an overall R(s)*T(p) function of the beamsplitter varies no more than ±2.74% in the range of 40-50 degrees of incidence.

Abstract: A method for reducing the scattered light emitted through an optical element is provided that protects adhesive used to hold the optical element in place from light induced deterioration. In one- embodiment, the method includes applying a thin coating of an organoxy metallic compound to a region on an optical element where adhesive will be applied and exposing the organoxy metallic compound to ultra-violet light. Exposure to ultra-violet light converts the organoxy metallic compound to its corresponding metal oxide forming an optically inert, light absorbing coating that protects adhesive used to hold the optical element in place from light induced deterioration.

Abstract: The present invention provides a photolithography system having a catadioptric system with a polarizing beam splitter cube. The beam splitter cube transmits light at wavelengths equal to or less than 170 nm. The polarizing beam splitter cube can image at high quality light incident over a wide range of angles and including a numeric aperture greater than 0.6. In one embodiment, the polarizing beam splitter cube comprises a pair of prisms that are made of at least a fluoride material, such as calcium fluoride, and a coating interface having at least one layer of a thin film fluoride material. Layers in a multi-layer stack can also be graded across the hypotenuse face of a prism to adjust layer thicknesses at any point so as to compensate for changes in the incidence angle of the light. In one embodiment, the prisms and coating interface are joined by optical contact.

Abstract: The present invention provides a ultraviolet (UV) polarizing beam splitter cube. The UV polarizing beam splitter cube is transmissive to light at wavelengths equal to or less than 170 nm, and for example at 157 nm. The UV polarizing beam splitter cube can image at high quality light incident over a wide range of angles and including a numeric aperture greater than 0.6, and for example at 0.75. In one embodiment, the UV polarizing beam splitter cube comprises a pair of prisms that are made of at least a fluoride material, and a coating interface having at least one layer of a thin film fluoride material. In one example implementation, a UV polarizing beam splitter cube comprises a pair of prisms that are made of at least calcium fluoride material, and a coating interface having a stack of alternating layers of thin film fluoride materials. The alternating layers of thin film fluoride materials comprise first and second fluoride materials.

Abstract: The present invention provides an ultraviolet (UV) polarizing beam splitter cube. The UV polarizing beam splitter cube is transmissive to light at wavelengths equal to or less than 170 nm and can image, at high quality, light incident over a wide range of angles and including a numeric aperture greater than 0.6. The UV polarizing beam splitter cube comprises a pair of prisms that are made of at least a fluoride material, and a coating interface having at least one layer of a thin film fluoride material. Alternating layers of thin film fluoride materials can comprise a first fluoride material having a first refractive index and a second fluoride material having a second refractive index. The first and second fluoride materials form a stack of fluoride materials having relatively high and low refractive indices such that the coating interface separates UV light into two polarized states.

Abstract: An ion beam sputtering process for fabricating a multilayer optical coating. The process adds energy to surface atoms of a sputtering target to increase deposition rates of atoms comprising the optical coating, thereby improving yield. The present process comprises providing a sputtering chamber. A sputtering target having a predetermined binding energy is disposed in the sputtering chamber, along with an optical element onto which a multilayer optical coating is to be deposited. The sputtering chamber is then pressurized to a predetermined sputtering pressure. Energy is then applied to the sputtering target to increase the vibrational energy of surface atoms and mean target energy thereof, thereby decreasing the amount of energy required to sputter atoms from the surface of the sputtering target onto the surface of the optical element.