The present invention provides an exposure apparatus that exposes a substrate, comprising: an optical system configured to emit, in a first direction, light for exposing the substrate; a first supplier configured to supply a gas into a chamber where the optical system is arranged; and a second supplier configured to supply a gas to an optical path space where the light from the optical system passes through, wherein the second supplier includes a gas blower including a blowing port from which a gas is blown out in a second direction, and the guide member configured to guide the gas blown out from the blowing port to the optical path space, and the guide member includes a plate member extended on a side of the first direction of the blowing port so as to be arranged along the second direction.

An extreme ultraviolet light generation apparatus includes a chamber including a first space and a second space; a first partition wall including a first opening through which extreme ultraviolet light passes; a connection portion connecting the chamber and an external apparatus; a second partition wall including a second opening through which the extreme ultraviolet light passes; a gas supply port which allows a gas to pass therethrough; a first exhaust port which opens to the first space; a second exhaust port which opens to a third space located inside the connection portion; a first sensor arranged in the third space; and a processor calculating a first passage flow rate of a gas passing through the first opening based on a measurement result of the first sensor and adjusting a supply flow rate of the gas to be supplied through the gas supply port based on the first passage flow rate.

A method comprises loading a wafer onto a wafer chuck of a lithography apparatus, projecting an extreme ultraviolet light through an opening of a frame structure of the lithography apparatus, onto the wafer, and introducing an airflow from an air curtain module on the wafer chuck toward the frame structure, wherein the air curtain module surrounds the wafer. The airflow forms an air curtain around the wafer, and shields the wafer from contaminants from the frame structure or a wafer stage.

An object stage that includes a first structure and a second structure movable relative to the first structure. The second structure is configured to support an object. The object stage also includes a seal plate movably coupled to the first structure or the second structure, but not both. Further, the object stage includes an actuator configured to move the seal plate such that a substantially constant gap is defined between the seal plate and the first structure or second structure that is not coupled to the seal plate.

A substrate processing apparatus includes: a processing chamber configured to process a substrate; a light source chamber including a light source configured to irradiate vacuum ultraviolet light onto a surface of the substrate; a gas supply configured to supply an inert gas into the light source chamber; and a controller that controls the gas supply to maintain the light source chamber in an inert gas atmosphere.

An apparatus comprising: a position monitoring system configured to determine the position of the substrate with respect to a projection system configured to project a radiation beam through an opening in the projection system and onto a substrate, wherein a component of the position monitoring system is located beneath the projection system in use; and a baffle disposed between the opening and the component.

An extreme ultra violet (EUV) lithography method includes receiving an EUV light by a scanner from an EUV light source, the EUV light passing through an intermediate focus disposed in the scanner and at a junction of the EUV light source and the scanner; directing the EUV light by the scanner to a reticle in the scanner; and deflecting nanoparticles from the EUV light source away from the reticle by generating a gas flow using a gas jet disposed entirely in the scanner and proximate to an interface of the scanner and the intermediate focus such that the gas jet does not block the EUV light.

A method comprises loading a wafer onto a wafer chuck of a lithography apparatus, projecting an extreme ultraviolet light through an opening of a frame structure of the lithography apparatus, onto the wafer, and introducing an airflow from an air curtain module on the wafer chuck toward the frame structure, wherein the air curtain module surrounds the wafer. The airflow forms an air curtain around the wafer, and shields the wafer from contaminants from the frame structure or a wafer stage.

An extreme ultraviolet (EUV) light generating apparatus includes a vessel including a first end and a second end opposite to each other and providing an internal space extending from the first end to the second end, a concave mirror adjacent to the first end of the vessel, a droplet generator supplying a droplet to the internal space of the vessel, a laser light source irradiating a laser beam to cause the droplet to emit EUV light, and a gas jet receiving a flow control gas and spraying the received flow control gas into the internal space of the vessel. The gas jet includes a ring-shaped main body including nozzles spaced apart from one another in a circumferential direction. The nozzles spray the received flow control gas in a downward direction.

An apparatus, which may form part of a lithographic apparatus, comprises a substrate table, a projection system, a gas lock and a gas flow guide. The substrate table is suitable for supporting a substrate. The projection system has a body which defines an interior and an opening. The projection system is configured and arranged to project a radiation beam through the opening onto a substrate supported by the substrate table. The gas lock is suitable for providing a gas flow from the opening away from the interior. The gas flow guide is configured to guide at least a portion of the gas flow away from the substrate supported by the substrate table.