An optical system for increasing contrast of pulsed laser radiation includes a first polarization setting optical unit for setting an elliptical polarization state of the pulsed laser radiation, and a multipass cell having at least two opposing mirrors. The pulsed laser radiation passes the multipass cell with formation of a plurality of intermediate focus zones. The multipass cell is filled with a gas having an optical nonlinearity that causes an intensity-dependent rotation of an alignment of the elliptical polarization state of the pulsed laser radiation, such that the multipass cell outputs beam portions having differently aligned elliptical polarization states on account of the intensity-dependent rotation. The optical system further includes an optical beam splitting system for splitting the beam portions having differently aligned elliptical polarization states.

An optical system for increasing contrast of pulsed laser radiation includes a first polarization setting optical unit for setting an elliptical polarization state of the pulsed laser radiation, and a multipass cell having at least two opposing mirrors. The pulsed laser radiation passes the multipass cell with formation of a plurality of intermediate focus zones. The multipass cell is filled with a gas having an optical nonlinearity that causes an intensity-dependent rotation of an alignment of the elliptical polarization state of the pulsed laser radiation, such that the multipass cell outputs beam portions having differently aligned elliptical polarization states on account of the intensity-dependent rotation. The optical system further includes an optical beam splitting system for splitting the beam portions having differently aligned elliptical polarization states.

A system includes: an optical source including a plurality of optical oscillators; a spectral analysis apparatus; and a controller. Each optical oscillator is configured to produce a light beam. The controller is configured to: determine, based on data from the spectral analysis apparatus, whether the spectral property of the light beam of one of the optical oscillators is different than the spectral property of the light beam of at least another of the plurality of optical oscillators. If the spectral property of the light beam of the first one of the optical oscillators is different than the spectral property of the light beam of another of the optical oscillators, the controller is configured to adjust the spectral property of the light beam of the first one of the optical oscillators or of the light beam of at least one other of the optical oscillators.

A system includes: an optical source including a plurality of optical oscillators; a spectral analysis apparatus; and a controller. Each optical oscillator is configured to produce a light beam. The controller is configured to: determine, based on data from the spectral analysis apparatus, whether the spectral property of the light beam of one of the optical oscillators is different than the spectral property of the light beam of at least another of the plurality of optical oscillators. If the spectral property of the light beam of the first one of the optical oscillators is different than the spectral property of the light beam of another of the optical oscillators, the controller is configured to adjust the spectral property of the light beam of the first one of the optical oscillators or of the light beam of at least one other of the optical oscillators.

A line narrowing device includes first and second prisms disposed at positions different in a wavelength dispersion direction of any of the first and second prisms, a third prism disposed on the optical path of an optical beam and through which the beam width of the optical beam is enlarged and first and second parts of the optical beam are incident on the first and second prisms, respectively, a grating disposed across the optical path of the first part having passed through the first prism and the optical path of the second part having passed through the second prism, a first actuator configured to adjust the incident angle of the first part on the grating, a second actuator configured to adjust the incident angle of the second part on the grating, and a third actuator configured to adjust an energy ratio of the first and second parts.

A control method of a line narrowing gas laser device includes receiving a command of either a single-wavelength mode command or a multi-wavelength mode command from an external apparatus, and controlling the line narrowing gas laser device to generate pulse laser light in accordance with the command.

A control method of a line narrowing gas laser device includes receiving a command of either a single-wavelength mode command or a multi-wavelength mode command from an external apparatus, and controlling the line narrowing gas laser device to generate pulse laser light in accordance with the command.

A laser device according to an aspect of the present disclosure includes a chamber into which laser gas is introduced; a pair of electrodes arranged in the chamber; a power source configured to apply a voltage between the electrodes; a nozzle structure which includes an internal passage for receiving the laser gas and a slit connected to the internal passage and is configured to generate flow of the laser gas between the electrodes due to the laser gas blowing out from the slit; a gas flow path which has a suction port through which the laser gas in the chamber is suctioned and introduces, to the nozzle structure, the laser gas suctioned through the suction port; and a blower device configured to cause the laser gas to blow toward the internal passage of the nozzle structure through the gas flow path.

A laser device according to an aspect of the present disclosure includes a chamber into which laser gas is introduced; a pair of electrodes arranged in the chamber; a power source configured to apply a voltage between the electrodes; a nozzle structure which includes an internal passage for receiving the laser gas and a slit connected to the internal passage and is configured to generate flow of the laser gas between the electrodes due to the laser gas blowing out from the slit; a gas flow path which has a suction port through which the laser gas in the chamber is suctioned and introduces, to the nozzle structure, the laser gas suctioned through the suction port; and a blower device configured to cause the laser gas to blow toward the internal passage of the nozzle structure through the gas flow path.

A laser chamber apparatus may include a pipe, an inner electrode extending along a longitudinal direction of the pipe and disposed in a through hole in the pipe, an outer electrode including a contact plate extending along the longitudinal direction of the pipe and being in contact with an outer circumferential surface of the pipe and a ladder section formed of bar members each having one end connected to the contact plate and juxtaposed along a longitudinal direction of the contact plate, and a leaf spring extending along the longitudinal direction of the pipe and configured to press the outer electrode against the pipe. The leaf spring may include leaf spring pieces separated by slits, and the leaf spring pieces may each include a bent section bent along the edge and are configured to press the bar members in a position shifted from the bent sections toward the edge.