A method for using an extreme ultraviolet radiation source is provided. The method includes assembling a first droplet generator onto a port of a vessel; ejecting a target droplet from the first droplet generator to a zone of excitation in front of a collector; emitting a laser toward the zone of excitation, such that the target droplet is heated by the laser to generate extreme ultraviolet (EUV) radiation; stopping the ejection of the target droplet; after stopping the ejection of the target droplet, disassembling the first droplet generator from the port of the vessel; after disassembling the first droplet generator from the port of the vessel, inserting a cleaning device into the vessel through the port; and cleaning the collector by using the cleaning device.

A method of producing a substrate holder for use in a lithographic apparatus, the substrate holder comprising a main body having a main body surface, wherein the method includes the steps of: coating at least part of the main body with a layer of a first coating material; and treating a plurality of discrete regions of the first coating material with laser irradiation to selectively convert said first coating material in said regions to a second coating material having a different structure or density.

A projection exposure apparatus for semiconductor lithography having a projection optical unit. The projection optical unit includes a sensor frame, a carrying frame, and a module. The module includes an optical element and actuators for positioning and orienting the optical element. The module is on the carrying frame, and the sensor frame is a reference for the positioning of the optical element. The module includes an infrastructure which includes interfaces for separating a module from the projection optical unit. A method exchanges the module of a projection optical unit of a projection exposure apparatus for semiconductor lithography, wherein the module includes an optical element, while the reference remains in the projection exposure apparatus.

An assembly for use with an extreme ultraviolet (EUV) chamber, along with methods of using such, are described. The assembly includes a ring structure. The ring structure includes an outer ring and an inner ring disposed radially inward of the outer ring. The assembly also includes a vacuum interface to be attached and in contact with the inner ring, wherein the inner ring has an opening that is size adjustable to allow a device to pass through and into the vacuum interface.

The instant disclosure discloses a workpiece container system comprising a storage assembly that comprises a seat member. The seat member has a storage portion that defines a longitudinal axis through a geometric center region thereof, provided with a workpiece receiving region that encompasses the geometric center region and configured to receive a workpiece. The seat member has a pair of flank portions arranged on opposite sides of the storage portion along the longitudinal axis, each having a thickness thinner than that of the storage portion. A diffuse inducing component is provided on the storage portion in the workpiece receiving region yet offsets the geometric center region thereof.

A substrate holder for a lithographic apparatus has a planarization layer provided on a surface thereof. The planarization layer provides a smooth surface for the formation of an electronic component such as a thin film electronic component. The planarization layer may be provided in multiple sub layers. The planarization layer may smooth over roughness caused by removal of material from a blank to form burls on the substrate holder.

An optical path compensation apparatus includes a wedge assembly, a driving mechanism and a preload unit. The wedge assembly includes a movable wedge and a fixed wedge. The movable wedge and the fixed wedge having equal wedge angles and respective wedge surfaces inclined in opposite directions. The preload unit is configured to elastically press the movable wedge on the fixed wedge, and the driving mechanism is configured to cause relative movement between the wedge surface of the movable wedge and the wedge surface of the fixed wedge. This optical path compensation apparatus is capable of achieving effective position correction of a focal plane of a measurement system for focusing and leveling in a smooth, convenient and precise way while not causing any error in other directions.

An apparatus for moving an object in and/or out of a housing, for example for moving a support structure for a mask out of a housing of a lithographic apparatus. The apparatus includes a first guiding mechanism moveable in a first direction and which is rotatably connectable to a first part of the object, and a second guiding mechanism moveable in a second direction and which is rotatably connectable to a second part of the object, wherein the second part is different from the first part and the second direction is different from the first direction. The rotatable connections define a rotation around an axis which extends in a third direction which is substantially perpendicular to the first direction and the second direction.

A system including: a substrate support configured to hold a substrate; a conductive or semi-conductive element contacting the substrate support and covering at least part of the substrate support; and a charging device configured to apply a positive potential to the conductive or semi-conductive element with respect to the part of the substrate support that is covered by the conductive or semi-conductive element.

A droplet catcher system of an EUV lithography apparatus is provided. The droplet catcher system includes a catcher body, a heat transfer part, a heat exchanger, and a controller. The catcher body has an outer surface. The heat transfer part is directly attached to the outer surface of the catcher body. The heat exchanger is thermally coupled to the heat transfer part. The controller is electrically coupled to the heat exchanger.