The excimer laser device receives data on a target value of pulse energy from an external device and outputs a pulse laser beam. The excimer laser device includes a master oscillator, at least one power amplifier including a chamber provided in an optical path of the pulse laser beam outputted from the master oscillator, a pair of electrodes provided in the chamber, and an electric power source configured to apply voltage to the pair of electrodes, and a controller configured to control the electric power source of one power amplifier of the at least one power amplifier to stop applying the voltage to the pair of electrodes based on the target value of the pulse energy.

A gas laser device may include: a laser chamber containing laser gas; a first discharge electrode disposed in the laser chamber; a second discharge electrode disposed to face the first discharge electrode in the laser chamber; and a condenser including a polyimide dielectric and configured to supply power to between the first discharge electrode and the second discharge electrode.

An excimer laser apparatus may include an optical resonator, a chamber including a pair of discharge electrodes, the chamber being provided in the optical resonator and configured to store laser gas, an electric power source configured to receive a trigger signal and apply a pulsed voltage to the pair of discharge electrodes based on the trigger signal, an energy monitor configured to measure pulse energy of a pulse laser beam outputted from the optical resonator, a unit for adjusting partial pressure of halogen gas configured to perform exhausting a part of the laser gas stored in the chamber and supplying laser gas to the chamber, and a controller configured to acquire measurement results of the pulse energy measured by the energy monitor, detect energy depression based on the measurement results of the pulse energy, and control the unit for adjusting partial pressure of halogen gas based on results of detecting the energy depression to adjust the partial pressure of halogen gas in the chamber.

Methods, devices, and apparatus for generating plasma or laser pulses by radio frequency (RF) excitation pulses are provided. In one aspect, a method includes specifying radio frequency (RF) excitation pulses at least partially as a function of a preceding RF excitation of a medium and outputting a signal to a RF pulse generator, the signal configured to cause the RF pulse generator to generate the specified RF excitation pulses for exciting the medium to generate plasma or laser pulses. The RF excitation pulses is specified to become more strongly reduced in energy when a remaining excitation of the medium by the preceding RF excitation is higher.

An excimer laser chamber device may include: a the laser chamber; a first electrode provided in the laser chamber; a second electrode provided in the laser chamber to face the first electrode; an electrode holder provided in the laser chamber to be connected to a high voltage; at least one connecting terminal including a first anchored portion anchored to the first electrode and a second anchored portion anchored to the electrode holder, the at least one connecting terminal being configured to electrically connect the first electrode and the electrode holder; a guide member held by the electrode holder, the guide member being configured to position the first electrode in a direction substantially perpendicular to both a direction of electric discharge between the first electrode and the second electrode and a longitudinal direction of the first electrode; and an electrode-gap-varying unit configured to move the first electrode in a direction substantially parallel to the direction of electric discharge.

The laser system includes a first laser apparatus, a second laser apparatus, a charging voltage measuring unit configured to measure the charging voltage of the first storage capacitor and the charging voltage of the second storage capacitor, at least one bleeding circuit configured to reduce the charging voltage of the first storage capacitor and the charging voltage of the second storage capacitor, and a bleeding circuit controller configured to control the at least one bleeding circuit based on the voltage measured by the charging voltage measuring unit.

The laser system may include a delay circuit unit, first and second trigger-correction units, and a clock generator. The delay circuit unit may receive a trigger signal, output a first delay signal obtained by delaying the trigger signal by a first delay time, and output a second delay signal obtained by delaying the trigger signal by a second delay time. The first trigger-correction unit may receive the first delay signal and output a first switch signal obtained by delaying the first delay signal by a first correction time. The second trigger-correction unit may receive the second delay signal and output a second switch signal obtained by delaying the second delay signal by a second correction time. The clock generator may generate a clock signal that is common to the delay circuit unit and the first and second trigger-correction units.

A gas laser excitation system with an integrated impedance matching circuit, comprises a gas laser electrode, a high-frequency connection line connectable to the gas laser electrode and configured for transmission of high-frequency power to the gas laser electrode, and a shield configured to shield the high-frequency power to be transmitted. The shield is arranged between the high-frequency connection line and the gas laser electrode. The high-frequency connection line interacts with the gas laser electrode and/or the shield in such a way that the resulting impedance changes at least across a section of the high-frequency connection line.

Problem: to suppress the number of times complete gas replacement in a laser chamber. Solution: this excimer laser apparatus may include a gas supply unit, connected to a first receptacle that holds a first laser gas containing halogen gas and a second receptacle that holds a second laser gas having a lower halogen gas concentration than the first laser gas, that supplies the first laser gas and the second laser gas to the interior of the laser chamber. Then, gas pressure control in which the gas supply unit supplies the second laser gas to the interior of the laser chamber or a gas exhaust unit partially exhausts gas from within the laser chamber, and partial gas replacement control in which the gas supply unit supplies the first laser gas and the second laser gas to the interior of the laser chamber and the gas exhaust unit partially exhausts gas from within the laser chamber sequentially, may be selectively performed.

The excimer laser device receives data on a target value of pulse energy from an external device and outputs a pulse laser beam. The excimer laser device includes a master oscillator, at least one power amplifier including a chamber provided in an optical path of the pulse laser beam outputted from the master oscillator, a pair of electrodes provided in the chamber, and an electric power source configured to apply voltage to the pair of electrodes, and a controller configured to control the electric power source of one power amplifier of the at least one power amplifier to stop applying the voltage to the pair of electrodes based on the target value of the pulse energy.