A mirror for EUV radiation includes a mirror body, which has at least one EUV radiation-reflecting region and at least two EUV radiation-permeable regions. A spatial separation of the illumination and imaging beam paths is possible with small angles of incidence and a large object-side numerical aperture.

Disclosed are a divisional exposure apparatus which allows for forming a PAC layer uniformly on RGBW subpixels by a single mask process, using divisional exposure, in a large-size liquid crystal display with a COT structure, and a method of manufacturing a liquid crystal display using the same. To this end, the sum of illumination intensities at the center of an overlap region is controlled in the range of 120% to 130%, and gradually increases from 100% at the edge (boundary) of the overlap region. Accordingly, the cell gap between the RGB subpixels and the W subpixel is made uniform, thus preventing the problem of spots.

A lithographic apparatus injects gas between a patterning device and a patterning device masking blade to help protect the patterning device from contamination. The gas may be injected into the space defined between the patterning device and the patterning device blade by one or more gas supply nozzles that are arranged on at least one side of the patterning device. The one or more gas supply nozzles are coupled to a frame which a patterning device support structure moves relative to. Each nozzle may be constructed and arranged to supply gas over at least the patterning region of the reflective patterning device.

Disclosed are a linear light source generator, a lenticular system used in the linear light source generator, and a stepper equipped with the linear light source generator. The linear light source generator uses a lenticular, and includes a light source and a lenticular system. A light exposure work of the stepper is performed based on a relative transfer between the linear light source generator, and a pattern film or a photo mask.

A reticle-masking structure is provided. The reticle-masking structure includes a magnetic substrate and a paramagnetic part disposed on the magnetic substrate. The paramagnetic part includes a plurality of fractions disposed on a plurality of protrusion structures. In some embodiments, the fractions are irregularly arranged. A method for forming a reticle-masking structure and an extreme ultraviolet apparatus are also provided.

A method of modifying a lithographic apparatus comprising an illumination system for providing a radiation beam, a support structure for supporting a patterning device to impart the radiation beam with a pattern in its cross-section, a first lens for projecting the radiation beam at the patterning device with a first magnification, a substrate table for holding a substrate, and a first projection system for projecting the patterned radiation beam at a target portion of the substrate with a second magnification. The first lens and the first projection system together provide a third magnification. The method comprises reducing by a first factor the first magnification to provide a second lens for projecting the radiation beam with a fourth magnification; and increasing by the first factor the second magnification to provide a second projection system for projecting the patterned radiation beam at the target portion of the substrate with a fifth magnification.

A self-damping shutter apparatus for use in an exposure system of a photolithography machine, comprising: at least two pieces of shutter blades (1) for cutting off light source to an exposure area when the shutter is closed; a shutter driving arm (2), for driving the shutter blades (1) to synchronically open or close; a magnetic damping brake motor (3), for driving or braking the shutter driving arm (2), and the magnetic damping brake motor (3) drives and brakes, via the shutter driving arm (2), the shutter blades (1). The self-damping shutter apparatus for use in the exposure system of the photolithography machine increases consistency of opening or closing the shutter blades, improves a light shading effect of the shutter apparatus in an exposure, and improves stability in the process of opening or closuring the shutter blades. When the shutter blades complete actions of opening or closing, current is not needed, the magnetic damping braking motor enables the shutter blades to maintain the state of opening or closing, shortens duration of control current, reduces heat dissipation, and saves energy.

Methods and apparatus for measuring a parameter of interest of a target structure formed on substrate are disclosed. In one arrangement, the target structure comprises a first sub-target and a second sub-target. The first sub-target comprises a first bias and the second sub-target comprises a second bias. The method comprises determining the parameter of interest using a detected or estimated reference property of radiation at a first wavelength scattered from the first sub-target and a detected or estimated reference property of radiation at a second wavelength scattered from the second sub-target. The first wavelength is different to the second wavelength.

An exposure apparatus for transferring a pattern from a reticle to a workpiece, a pellicle being positioned near the reticle, includes a heat transfer frame, an illuminator, and a temperature controller. The heat transfer frame is configured to be positioned near the pellicle, the heat transfer frame defining a beam aperture. The illuminator directs a beam through the beam aperture and the pellicle at the reticle. The temperature controller controls the temperature of the heat transfer frame to control the temperature of the pellicle. The illuminator can direct the beam from a beam source, such as an EUV beam source. Additionally, the temperature controller can cryogenically cool the heat transfer frame.

A method of controlling output of a radiation source, the method including: periodically monitoring an output energy of the radiation source; determining a difference between a reference energy signal and the monitored output energy; determining a feedback value; determining a desired output energy of the radiation source for a subsequent time period; and controlling an input parameter of the radiation source in dependence on the determined desired output energy during the subsequent time period. If the magnitude of the determined difference between the monitored output energy of the radiation source and the reference energy signal exceeds a threshold value: the determined difference does not contribute to the feedback value; and the determined difference is spread over the subsequent time period according to a reference energy signal adjustment profile and the reference energy signal adjustment profile is added to the reference energy signal for the subsequent time period.