Abstract: A foil trap is located in a path of a radiation beam. The foil trap includes an array of conductive strips. A voltage application circuit is coupled to the strips to apply voltage differences between pairs of adjacent ones of the strips. The voltage application circuit includes a current limiting circuit arranged to limit currents to the strips to values below a threshold value above which self-sustained arc discharge may arise in the foil trap.

Abstract: A lithographic apparatus is arranged to project a beam from a radiation source onto a substrate. The apparatus includes an optical element in a path of the beam, a gas inlet for introducing a gas into the path of the beam so that the gas will be ionized by the beam to create electric fields toward the optical element, and a gas source coupled to the gas inlet for supplying the gas. The gas has a threshold of kinetic energy for sputtering the optical element that is greater than the kinetic energy developed by ions of the gas in the electric fields.

Abstract: A device for generating radiation or a source based on a discharge includes a cathode and an anode. The cathode and anode material are supplied in fluid state. The material forms a plasma pinch when the device is in use. Optionally, nozzles may be used to supply the material. The cathode and/or anode may form a flat surface. The trajectories of the material may be elongated. A laser may be used to cause the discharge more easily. The laser may be directed on the anode of cathode or on a separate material located in between the anode and cathode.

Abstract: A device for generating radiation source based on a discharge includes a cathode and an anode. The cathode and anode material are supplied in fluid state. The material forms a plasma pinch when the device is in use. Optionally, nozzles may be used to supply the material. The cathode and/or anode may form a flat surface. The trajectories of the material may be elongated. A laser may be used to cause the discharge more easily. The laser may be directed on the anode of cathode or on a separate material located in between the anode and cathode.

Abstract: A radiation source unit is provided that includes an anode and a cathode that are configured and arranged to create a discharge in a substance in a space between said anode and cathode and to form a plasma so as to generate electromagnetic radiation. The substance may comprise xenon, indium, lithium, tin or any suitable material. To improve conversion efficiency, the source unit may be constructed to have a low inductance, and operated with a minimum of plasma. To, for example, improve heat dissipation, a fluid circulation system can be created within the source volume and a wick by using a fluid in both its vapor and liquid states. To, for example, prevent contamination from entering a lithographic projection apparatus, the source unit can be constructed to minimize the production of contamination, and a trap can be employed to capture the contamination without interfering with the emitted radiation.

Abstract: A lithographic apparatus is disclosed. The apparatus includes an illumination system that provides a beam of radiation, and a support structure that supports a patterning structure. The patterning structure is configured to impart the beam of radiation with a pattern in its cross-section. The apparatus also includes a substrate support that supports a substrate, a projection system that projects the patterned beam onto a target portion of the substrate, and a debris-mitigation system that mitigates debris particles which are formed during use of at least a part of the lithographic apparatus. The debris-mitigation system is arranged to apply a magnetic field so that at least charged debris particles are mitigated.