A microscope system for flexibly, efficiently and quickly inspecting patterns and defects on extreme ultraviolet (EUV) lithography photomasks. The system includes a stand-alone plasma-based EUV radiation source with an emission spectrum with a freestanding line emission in the spectral range from 12.5 nm to 14.5 nm has a relative bandwidth of λ/Δλ>1000, means for the broadband spectral filtering λ/Δλ<50 for selecting the dominant freestanding emission line, means for suppressing radiation with wavelengths outside of the EUV spectral region, zone plate optics for magnified imaging of the object with a resolution which corresponds to the width of an outermost zone of the zone plate, a numerical aperture corresponding to more than 1000 zones, and a EUV detector array for capturing the patterned object.

An amorphous layer is used as a protective coating for hygroscopic nonlinear optical crystals. The amorphous layer consists of one or more alkali metal borates and/or alkali earth metal borates. The amorphous layer slows or prevents water and/or oxygen from diffusing into the hygroscopic nonlinear optical crystal, thus simplifying handling, storage and operating environmental requirements. One or multiple additional coating layers may be placed on top of the amorphous layer, with the additional coating layers including conventional optical materials. The thicknesses of the amorphous layer and/or additional layers may be chosen to reduce reflectance of the optical component at one or more specific wavelengths. The coated nonlinear optical crystal is used in an illumination source utilized in a semiconductor inspection system, a metrology system, or a lithography system.

A method includes: receiving a photomask; patterning a wafer by directing a first radiation beam to the wafer through the photomask at a first tilt angle; and inspecting the photomask. The inspecting includes: directing a second radiation beam to the photomask at a second tilt angle greater than the first tilt angle; receiving a third radiation beam reflected from the photomask; and generating an image of the photomask according to the third radiation beam.

A method includes: receiving a photomask; patterning a wafer by directing a first radiation beam to the wafer through the photomask at a first tilt angle; and inspecting the photomask. The inspecting includes: directing a second radiation beam to the photomask at a second tilt angle greater than the first tilt angle; receiving a third radiation beam reflected from the photomask; and generating an image of the photomask according to the third radiation beam.

A broadband light source includes a rotatable drum coated with plasma-forming target material, a rotational actuator configured to rotate the rotatable drum, and a rotary encoder connected to the rotatable drum. The broadband light source may include a linear actuator configured to axially translate the rotatable drum and linear encoder connected to the rotatable drum. The broadband light source includes a pulsed laser source configured to direct pulsed illumination to a set of spots on the material-coated portion of the rotatable drum for exciting the plasma-forming target material and emitting broadband light as the drum is actuated. The broadband light source includes a control system. The control system is configured to receive one or more rotational position indicators from the rotary indicator and control triggering of the laser source based on the one or more rotational position indicators from rotary encoder.

A pattering device inspection apparatus, system and method are described. According to one aspect, an inspection method is disclosed, the method including receiving, at a multi-element detector within an inspection system, radiation scattered at a surface of an object. The method further includes measuring, with processing circuitry, an output of each element of the multi-element detector, the output corresponding to the received scattered radiation. Moreover, the method includes calibrating, with the processing circuitry, the multi-element detector by identifying an active pixel area comprising one or more elements of the multi-element detector with a measured output being above a predetermined threshold. The method also includes identifying an inactive pixel area comprising a remainder of elements of the multi-element detector. Additionally, the method includes setting the active pixel area as a default alignment setting between the multi-element detector and a light source causing the scattered radiation.

To measure an effect of a wavelength-dependent measuring light reflectivity R.sub.Ret of a lithography mask, a measuring light beam is caused to impinge on said lithography mask within a field of view of a measuring apparatus. The measuring light has a wavelength bandwidth between a wavelength lower limit and a wavelength upper limit differing therefrom. The reflected measuring light emanating from an impinged section of the lithography mask is captured by a detector. A filter with a wavelength-dependent transmission within the wavelength bandwidth is introduced into a beam path of the measuring light beam between the measuring light source and the detector. The measuring light reflected by the lithography mask is captured again by the detector once the filter has been introduced. The wavelength-dependent reflectivity R.sub.Ret or an effect of the wavelength-dependent reflectivity R.sub.Ret is determined on the basis of the capture results. In comparison with the prior art, this yields an improved method for measuring an effect of a measuring light reflectivity on a lithography mask. Additionally, a method for measuring an effect of a polarization of measuring light on a measuring light impingement on a lithography mask is specified, wherein as a result of this the effect of the lithography mask on measuring light is made accessible in respect of further optical parameters of a measurement.

Provided is a substrate with a multilayer reflective film, the substrate being used for manufacturing a reflective mask blank and a reflective mask each having a multilayer reflective film having a high reflectance to exposure light and a low background level during defect inspection.

A substrate with a multilayer reflective film 110 comprises a substrate 1 and a multilayer reflective film 5. The multilayer reflective film 5 is formed of a multilayer film in which a low refractive index layer and a high refractive index layer are alternately layered on the substrate 1. The multilayer reflective film 5 comprises at least one additive element selected from hydrogen (H), deuterium (D), and helium (He). The additive element in the multilayer reflective film 5 has an atomic number density of 0.006 atom/nm.sup.3 or more and 0.50 atom/nm.sup.3 or less.

A pupil stop serves for use in an illumination optical unit of a metrology system for determining, as a result of illumination and imaging under illumination and imaging conditions corresponding to those of an optical production system, an aerial image of an object to be measured. The pupil stop has two pole passage openings for specifying a respective pole of an illumination of the illumination optical unit specified by the pupil stop. In each case at least one stop web passes through the respective pole passage opening and consequently divides the pole passage opening into a plurality of partial pole openings. This yields a pupil stop with which an accuracy of a convergence of the illumination and imaging conditions of the optical production system to the illumination and imaging conditions of the optical measurement system can be improved.

A method and a system for inspecting an extreme ultra violet mask and a mask pod for such masks is provided. An EUV mask inspection tool inspects a mask retrieved from a mask pod placed on the load port positioned exterior of the mask inspection tool. The inspection process is performed during a selected period of time. After the inspection process is initiated, a robotic handling mechanism such as a robotic arm or an AMHS picks up the mask pod and inspects the mask pod for foreign particles. A mask pod inspection tool determines whether the mask pod needs cleaning or replacing based on a selected swap criteria. The mask pod is retrieved from the mask pod inspection tool and placed on the load port before the selected period of time lapses. This method and system promotes a reduction in the overall time required for inspecting the mask and the mask pod.