A method of manufacturing an integrated circuit (IC) device includes forming a photoresist layer on a substrate, and exposing the photoresist layer to light by using a photolithographic apparatus including a light generator. The light generator includes a chamber having a plasma generation space, an optical element in the chamber, and a debris shielding assembly between the optical element and the plasma generation space in the chamber, and the debris shielding assembly includes a protective film facing the optical element and being spaced apart from the optical element with a protective space therebetween, the protective space including an optical path, and a protective frame to support the protective film and to shield the protective space from the plasma generation space.

A photolithography system utilizes tin droplets to generate extreme ultraviolet radiation for photolithography. The photolithography system irradiates the droplets with a laser. The droplets become a plasma and emit extreme ultraviolet radiation. The photolithography system senses contamination of a collector mirror by the tin droplets and adjusts the flow of a buffer fluid to reduce the contamination.

An extreme ultra violet (EUV) radiation source apparatus includes a collector mirror, a target droplet generator for generating a tin (Sn) droplet, a rotatable debris collection device, one or more coils for generating an inductively coupled plasma (ICP), a gas inlet for providing a source gas for the ICP, and a chamber enclosing at least the collector mirror and the rotatable debris collection device. The gas inlet and the one or more coils are configured such that the ICP is spaced apart from the collector mirror.

A collector mirror for an extreme ultraviolet (EUV) light generator includes a first mirror in a vessel, the vessel being configured to receive a material and a laser beam for generating the EUV light, a second mirror surrounding the first mirror, and a detachable third mirror between the first mirror and the second mirror, the third mirror having an inner diameter that is not smaller than an outer diameter of the first mirror, and an outer diameter that is not larger than an inner diameter of the second mirror.

In a method for producing an optical element for an EUV projection exposure apparatus, a shaping layer (22.sub.1) is applied onto a substrate (20) so as to have a surface roughness of at most 0.5 nm rms directly after the application of the shaping layer onto the substrate.

An extreme ultraviolet light generation apparatus includes a first chamber, an EUV light concentrating mirror arranged in the first chamber and configured to concentrate extreme ultraviolet light generated at a first point in the first chamber onto a second point, a first planar mirror arranged on an optical path of the extreme ultraviolet light reflected by the EUV light concentrating mirror, a second chamber accommodating the first planar mirror, a flexible tube arranged between the first and second chambers, an alignment optical system arranged at the first chamber and configured to cause alignment light to be incident on the EUV light concentrating mirror, a detector arranged at the second chamber and configured to detect the alignment light reflected by the EUV light concentrating mirror, an actuator configured to change posture of the first planar mirror, and a processor configured to control the actuator based on output of the detector.

A mirror, e.g. for a microlithographic projection exposure apparatus, includes an optical effective surface, a mirror substrate, a reflection layer stack for reflecting electromagnetic radiation incident on the optical effective surface, at least one first electrode arrangement, at least one second electrode arrangement, and an actuator layer system situated between the first and the second electrode arrangements. The actuator layer system is arranged between the mirror substrate and the reflection layer stack, has a piezoelectric layer, and reacts to an electrical voltage applied between the first and the second electrode arrangements with a deformation response in a direction perpendicular to the optical effective surface. The deformation response varies locally by at least 20% in PV value for a predefined electrical voltage that is spatially constant across the piezoelectric layer.

A light source is provided capable of maintaining the temperature of a collector surface at or below a predetermined temperature. The light source in accordance with various embodiments of the present disclosure includes a processor, a droplet generator for generating a droplet to create extreme ultraviolet light, a collector for reflecting the extreme ultraviolet light into an intermediate focus point, a light generator for generating pre-pulse light and main pulse light, and a thermal image capture device for capturing a thermal image from a reflective surface of the collector.

In a method of generating extreme ultraviolet (EUV) radiation in a semiconductor manufacturing system one or more streams of a gas is directed, through one or more gas outlets mounted over a rim of a collector mirror of an EUV radiation source, to generate a flow of the gas over a surface of the collector mirror. The one or more flow rates of the one or more streams of the gas are adjusted to reduce an amount of metal debris deposited on the surface of the collector mirror.

A method for using an extreme ultraviolet radiation source is provided. The method includes performing a lithography process using an extreme ultraviolet (EUV) radiation source; after the lithography processes, inserting an extraction tube into a vessel of the EUV radiation source; and cleaning a collector of the EUV radiation source by using the extraction tube.