A lithography system includes a radiation source and a photomask. The radiation source is configured to generate electromagnetic radiation traveling towards the photomask. The lithography system also includes an incident channel between the radiation source and the photomask for the electromagnetic radiation to travel through. There are a first injection nozzle configured to generate a first particle shield between the photomask and an exit port of the incident channel and a second injection nozzle configured to generate a second particle shield inside the incident channel.

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 reticle masking blade positioning to minimize the impact on critical dimension uniformity includes determining a target location of a reticle masking blade relative to a reflective reticle and positioning the reticle masking blade at the target location. A position of the reticle masking blade is monitored during an imaging operation. The position of the reticle masking blade is compared with the target location and the position of the reticle masking blade is adjusted if the position of the reticle masking blade is outside a tolerance of the target location.

A reticle-masking structure is provided. The reticle-masking structure includes a magnetic substrate and a paramagnetic part disposed on the magnetic substrate. The magnetic substrate has a magnetic field, and the paramagnetic part has an induced magnetic field in a direction of the magnetic field of the magnetic substrate. The paramagnetic part includes a rough surface defined by a plurality of protrusion structures of the paramagnetic part. A method for forming a reticle-masking structure and an extreme ultraviolet apparatus are also provided.

Disclosed are a system for fabricating a semiconductor device and a method of fabricating a semiconductor device. The system may include a chamber, an extreme ultraviolet (EUV) source in the chamber and configured to generate an EUV beam, an optical system on the EUV source and configured to provide the EUV beam to a substrate, a substrate stage in the chamber and configured to receive the substrate, a reticle stage in the chamber and configured to hold a reticle that is configured to project the EUV beam onto the substrate, and a particle collector between the reticle and the optical system and configured to allow for a selective transmission of the EUV beam and to remove a particle.

According to one embodiment, a correction plot in which a slit width is set different depending on overlay deviation in a shot region is generated. Then, a light-exposure scanning speed defined by a relative speed between a photomask stage with a photomask mounted thereon and a stage with a processing object mounted thereon is set, to obtain a desired light-exposure amount at each coordinate position, in accordance with the slit width in the correction plot. Then, a light-exposure process is performed, while controlling the slit width of a light-exposure slit, the photomask stage, and the stage, in accordance with the correction plot and the light-exposure scanning speed.

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.

A method of controlling reticle masking blade positioning to minimize the impact on critical dimension uniformity includes determining a target location of a reticle masking blade relative to a reflective reticle and positioning the reticle masking blade at the target location. A position of the reticle masking blade is monitored during an imaging operation. The position of the reticle masking blade is compared with the target location and the position of the reticle masking blade is adjusted if the position of the reticle masking blade is outside a tolerance of the target location.

An extreme ultraviolet lithography system (10) that creates a pattern (230) having a plurality of densely packed parallel lines (232) on a workpiece (22) includes a patterning element (16); an EUV illumination system (12) that directs an extreme ultraviolet beam (13A) at the patterning element (16); a projection optical assembly (18) that directs the extreme ultraviolet beam diffracted off of the patterning element (16) at the workpiece (22); and a pattern blind assembly (26) positioned in a beam path (55) of the extreme ultraviolet beam (13A). The pattern blind assembly (26) shapes the extreme ultraviolet beam (13A) so that an exposure field (28) on the workpiece (22) has a polygonal shape.

The invention provides a light generating method and system, the method including: generating first light, the first light being capable of forming a first area, a second area, and a third area, and intensity of the first light in the first area being higher than that in the second area and the third area, respectively; generating second light, the second light being capable of simultaneously irradiating the first area and the second area; generating third light, the third light being capable of simultaneously irradiating the first area and the third area; and controlling intensity of the second light and the third light, respectively. The light generating method and system provided by the invention can not only generate light having a super-resolution that may approach infinitesimal in theory but also employ light output by a laser as the only original light source, featuring extremely low costs and freedom from the diffraction limit of the light source, showing a great prospect of applications in the field of lithography.