A lithography apparatus is provided. The lithography apparatus includes a wafer stage configured to secure a semiconductor wafer and having a plurality of electrodes. The lithography apparatus also includes an exposure tool configured to perform an exposure process by projecting an extreme ultraviolet (EUV) light on the semiconductor wafer. The lithography apparatus further includes a controller configured to control power supplied to the electrodes to have a first adjusted voltage during the exposure process for a first group of exposure fields on the semiconductor wafer so as to secure the semiconductor wafer to the wafer stage. The first adjusted voltage is in a range from about 1.6 kV to about 3.2 kV.

An apparatus for processing the substrate includes a substrate stage and a source. The substrate stage is configured to support a substrate thereon. The substrate stage includes a substrate support formed with a first opening therein. The first opening is an annular opening. The source is coupled to the first opening and is configured to supply first gas/air to a bottom surface of the substrate through the first opening.

An apparatus for cleaning an electrostatic reticle holder used in a lithography system includes a chamber for providing a low pressure environment for the electrostatic reticle holder and an ultrasound transducer configured to apply ultrasound waves to the electrostatic reticle holder. The apparatus further includes a controller configured to control the ultrasound transducer and a gas flow controller. The gas flow controller is configured to enable pressurizing or depressurizing the chamber.

A substrate holder for a lithographic apparatus has a main body having a thin-film stack provided on a surface thereof. The thin-film stack forms an electronic or electric component such as an electrode, a sensor, a heater, a transistor or a logic device, and has a top isolation layer. A plurality of burs to support a substrate are formed on the thin-film stack or in apertures of the thin-film stack.

The present disclosure provides a method for lithography system that includes one or more thermal sensors that provide feedback to a thermal management controller. The thermal management controller provides instructions to a thermal regulation component such as a heat exchanger and gas jets to provide cooling of a reticle used in the lithography system.

An object holder for a lithographic apparatus has a main body having a surface. A plurality of burls to support an object is formed on the surface or in apertures of a thin-film stack. At least one of the burls is formed by laser-sintering. At least one of the burls formed by laser-sintering may be a repair of a damaged burl previously formed by laser-sintering or another method.

An improved stage for the processing of large, thin substrates, such as glass and semiconductor panels. Processing includes lithography, inspection, metrology, grinding, and the like. The stage includes a chuck that moves over a base relative to a device for processing a substrate. The chuck conforms to a geometry of the base while moving relative to the base.

Methods and systems are described for cleaning a support such as a clamp of a chuck that holds a patterning device or a wafer in a lithographic apparatus. The method includes loading a electrostatic cleaning substrate into a lithographic apparatus. The electrostatic cleaning substrate includes at least one electrode. The method further includes bringing the electrostatic cleaning substrate near to the clamping surface to be cleaned and connecting the electrode to a voltage source. Particles present on the support are then transferred to the electrostatic cleaning substrate.

A reticle holding tool is provided. The reticle holding tool includes a housing, a reticle chuck, and a gas delivery assembly. The housing includes an opening, a top housing member, and a lateral housing member extending from the top housing member and terminating at a lower edge which is located on a predetermined plane. The reticle chuck is positioned in the housing and has an effective surface configured to secure a reticle. The effective surface is located between the predetermined plane and the top housing member. The reticle chuck is movable between two boundary lines that are perpendicular to the effective surface. A width of the opening is greater than a distance between the two boundary lines. The gas delivery assembly is positioned within the housing and configured to supply gas into the housing.

A method for preventing photomask contamination includes generating a first electric field from an electrostatic chuck to attract a charged particle onto the electrostatic chuck, controlling the first electric field to detach the charged particle from the electrostatic chuck, and generating a second electric field below the electrostatic chuck to attract the charged particle.