Abstract: A radiation source apparatus is provided. The radiation source apparatus includes a chamber, an exhaust module, a measuring device, a gas supply module and a controller. The exhaust module is configured to extract debris caused by unstable target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The gas supply module is configured to provide a gas into the chamber according to a second gas flow rate. The controller is configured to adjust the first gas flow rate and the second gas flow according to the measured concentration of the debris.

Abstract: A light source for EUV is provided. The light source includes a target droplet generator, a laser generator, and a controller. The target droplet generator is configured to provide target droplets to a source vessel. The laser generator is configured to provide first laser pulses according to a control signal to irradiate the target droplets in the source vessel. The controller is configured to provide the control signal according to at least two of process parameters including temperature of the source vessel, droplet positions of the target droplets, and beam sizes and focal points of the first laser pulses. When the average value or the standard deviation of the temperature of the source vessel and the droplet positions of the target droplets exceed the predetermined range, the controller is configured to provide the control signal to the laser generator to stop providing the first laser pulses.

Abstract: An extreme ultraviolet (EUV) lithography system includes a vane bucket module. The vane bucket module includes a collecting tank and a temperature adjusting pack. The collecting tank has a cover and the cover includes a plurality of through holes. Thicknesses of edges of the cover is greater than a thickness of a center of the cover. The temperature adjusting pack surrounds the collecting tank. The temperature adjusting pack includes a plurality of inlets aligned with the through holes.

Abstract: An illuminator includes a first facet mirror receiving and reflecting an exposure radiation, an adjustable shielding element disposed on the first facet mirror, the adjustable shielding element adjusting intensity uniformity of the exposure radiation reflected by the first facet mirror, and a second facet mirror receiving and reflecting the exposure radiation reflected by the first facet mirror.

Abstract: A source for generating extreme ultraviolet (EUV) radiation includes a chamber enclosing a low pressure environment. A gas inlet is configured to provide a cleaning gas in the chamber. A plurality of exhaust ports, each having a corresponding gate valve including a scanner gate valve corresponding to an exhaust port separating the chamber from an EUV scanner are provided to the chamber. A pressure sensor is disposed inside the chamber and adjacent to the scanner gate valve. A controller is configured to control the gate valves other than the scanner gate valve based on an output of the pressure sensor.

Abstract: A radiation source apparatus is provided. The radiation source apparatus includes a chamber, an exhaust module, a measuring device, a gas supply module and a controller. The exhaust module is configured to extract debris caused by unstable target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The gas supply module is configured to provide a gas into the chamber according to a second gas flow rate. The controller is configured to adjust the first gas flow rate and the second gas flow according to the measured concentration of the debris.

Abstract: A light source for extreme ultraviolet (EUV) radiation is provided. The light source includes a target droplet generator, a laser generator, a measuring device, and a controller. The target droplet generator is configured to provide a plurality of target droplets to a source vessel. The laser generator is configured to provide a plurality of first laser pulses according to a control signal to irradiate the target droplets in the source vessel, so as to generate plasma as the EUV radiation. The measuring device is configured to measure process parameters including temperature of the source vessel, droplet positions of the target droplets, and beam sizes and focal points of the first laser pulses. The controller is configured to provide the control signal according to at least two of the process parameters.

Abstract: A radiation source apparatus includes a vessel, a laser, a collector, a container, and a cone structure. The vessel has an exit aperture. The laser is at one end of the vessel and configured to excite a target material to form a plasma. The collector is in the vessel and configured to collect at least radiation of a desired wavelength emitted by the plasma and to direct the collected radiation to the exit aperture of the vessel. The container is configured to receive a residue of the plasma. The cone structure is between the collector and the exit aperture and located besides the container. The cone structure includes a first inner sidewall, and a second inner sidewall adjoining the first inner sidewall and closer to the container than the first inner sidewall, and a first baffle assembly on the first inner sidewall.

Abstract: A radiation source apparatus includes a vessel, a laser, a collector, a container, and a cone structure. The vessel has an exit aperture. The laser is at one end of the vessel and configured to excite a target material to form a plasma. The collector is in the vessel and configured to collect at least radiation of a desired wavelength emitted by the plasma and to direct the collected radiation to the exit aperture of the vessel. The container is configured to receive a residue of the plasma. The cone structure is between the collector and the exit aperture and located besides the container. The cone structure includes a first inner sidewall, and a second inner sidewall adjoining the first inner sidewall and closer to the container than the first inner sidewall, and a first baffle assembly on the first inner sidewall.

Abstract: A radiation source apparatus is provided. The radiation source apparatus includes a chamber, a target droplet generator, an exhaust module, a measuring device, and a controller. The target droplet generator is configured to provide a plurality of target droplets to the chamber. The exhaust module is configured to extract debris corresponding to the target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The controller is configured to adjust the first gas flow rate according to the measured concentration of the debris.

Abstract: A source for generating extreme ultraviolet (EUV) radiation includes a chamber enclosing a low pressure environment. A gas inlet is configured to provide a cleaning gas in the chamber. A plurality of exhaust ports, each having a corresponding gate valve including a scanner gate valve corresponding to an exhaust port separating the chamber from an EUV scanner are provided to the chamber. A pressure sensor is disposed inside the chamber and adjacent to the scanner gate valve. A controller is configured to control the gate valves other than the scanner gate valve based on an output of the pressure sensor.

Abstract: A radiation source apparatus is provided. The radiation source apparatus includes a chamber, a target droplet generator, an exhaust module, a measuring device, and a controller. The target droplet generator is configured to provide a plurality of target droplets to the chamber. The exhaust module is configured to extract debris corresponding to the target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The controller is configured to adjust the first gas flow rate according to the measured concentration of the debris.

Abstract: An extreme ultraviolet radiation source is provided, including a droplet generator and a droplet catcher. The droplet generator is configured to output a plurality of target droplets along a target droplet path that is parallel to a horizontal direction. The droplet catcher includes an open end substantially aligned with the target droplet path, and an enclosed end that is opposite to the open end. The droplet catcher also includes a pipe wall disposed between the open end the enclosed end. The pipe wall includes a first pipe wall portion having an inner top surface parallel to the horizontal direction and an inner bottom surface inclined relative to the inner top surface. In addition, the droplet catcher includes at least one gutter formed on the inner bottom surface and having a long axis extending along the horizontal direction.

Abstract: A radiation source apparatus is provided. The radiation source apparatus includes a chamber, a target droplet generator, an exhaust module, a measuring device, and a controller. The target droplet generator is configured to provide a plurality of target droplets to the chamber. The exhaust module is configured to extract debris corresponding to the target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The controller is configured to adjust the first gas flow rate according to the measured concentration of the debris.

Abstract: A light source for extreme ultraviolet (EUV) radiation is provided. The light source includes a target droplet generator, a laser generator, a measuring device, and a controller. The target droplet generator is configured to provide a plurality of target droplets to a source vessel. The laser generator is configured to provide a plurality of first laser pulses according to a control signal to irradiate the target droplets in the source vessel, so as to generate plasma as the EUV radiation. The measuring device is configured to measure process parameters including temperature of the source vessel, droplet positions of the target droplets, and beam sizes and focal points of the first laser pulses. The controller is configured to provide the control signal according to at least two of the process parameters.

Abstract: A radiation source apparatus is provided. The radiation source apparatus includes a chamber, a target droplet generator, an exhaust module, a measuring device, and a controller. The target droplet generator is configured to provide a plurality of target droplets to the chamber. The exhaust module is configured to extract debris corresponding to the target droplets out of the chamber according to a first gas flow rate. The measuring device is configured to measure concentration of the debris in the chamber. The controller is configured to adjust the first gas flow rate according to the measured concentration of the debris.

Abstract: The invention provides a method for manufacturing a thin film substrate. The method comprises steps of: providing a substrate having at least one through hole; forming a first metallic layer on a surface of the substrate and the through holes; forming a resist layer and a first opening on the first metallic layer; forming a second metallic layer in the first opening and the through hole; removing the resist layer and a part of the first metallic layer to form a circuit layer and a plurality of grooves; forming a solder mask layer on the circuit layer and in the groove, and forming a second opening on the solder mask layer to expose a part of the circuit layer; and polishing the surface of the exposed circuit layer and the solder mask layer.