A cleaning machine and a cleaning method for a photomask pellicle are provided. The cleaning machine at least includes: an air knife and a cleaning device. The air knife is configured to blow away contamination particles on the surface of the photomask pellicle. The cleaning device is configured to spray cleaning liquid to the surface of the photomask pellicle, to weather the contamination particles failed to be blown away by the air knife through the volatilization of the cleaning liquid. The air knife is also configured to blow away the weathered contamination particles.

The prevent disclosure provides a method for forming a reflective mask. In some embodiments, the method includes forming a carbon-containing layer over a substrate; forming a reflective multilayer over the carbon-containing layer; forming an absorption pattern over the reflective multilayer. In some embodiments, the method includes growing a light absorbing layer over a substrate; polishing the light absorbing layer; forming a reflective layer over the polished light absorbing layer; forming an absorption pattern over the reflective layer.

The prevent disclosure provides a method for forming a reflective mask. In some embodiments, the method includes forming a carbon-containing layer over a substrate; forming a reflective multilayer over the carbon-containing layer; forming an absorption pattern over the reflective multilayer. In some embodiments, the method includes growing a light absorbing layer over a substrate; polishing the light absorbing layer; forming a reflective layer over the polished light absorbing layer; forming an absorption pattern over the reflective layer.

An integrated circuit includes a first set of devices, a set of metal layers and a header circuit. The first set of devices are configured to operate on a first supply voltage, and are located on a first layer of the integrated circuit. The set of metal layers are above the first layer, and includes a first metal layer and a second metal layer. The first metal layer extends in at least a first direction and a second direction. The header circuit is above the first set of devices. At least a portion of the header circuit is positioned between the first metal layer and the second metal layer. The header circuit is configured to provide the first supply voltage to the first set of devices, and is configured to be coupled to a first voltage supply having the first supply voltage.

An integrated circuit includes a first set of devices, a set of metal layers and a header circuit. The first set of devices are configured to operate on a first supply voltage, and are located on a first layer of the integrated circuit. The set of metal layers are above the first layer, and includes a first metal layer and a second metal layer. The first metal layer extends in at least a first direction and a second direction. The header circuit is above the first set of devices. At least a portion of the header circuit is positioned between the first metal layer and the second metal layer. The header circuit is configured to provide the first supply voltage to the first set of devices, and is configured to be coupled to a first voltage supply having the first supply voltage.

A substrate processing apparatus of an embodiment includes a nozzle plate and a support configured to support a substrate at a predetermined distance from the nozzle plate with a first surface of the substrate facing the nozzle plate. A processing liquid supply unit is configured to supply a processing liquid to a second surface of the substrate that is opposite to the first surface. A first supply unit is configured to supply a first fluid from a first supply port in the nozzle plate. A second supply unit is configured to supply a second fluid from a second supply port closer to a outer edge of the nozzle plate than the first supply port.

A method for preparing a biological material for implanting provides irradiating at least a portion of the surface of the material with an accelerated Neutral Beam.

A method for preparing a biological material for implanting provides irradiating at least a portion of the surface of the material with an accelerated Neutral Beam.

An photolithographic apparatus includes a particle removing cassette selectively extendable from the processing apparatus. The particle removing cassette includes a wind blade slit and an exhausting slit. The wind blade slit is configured to direct pressurized cleaning material to a surface of the mask to remove the debris particles from the surface of the mask. The exhausting slit collects the debris particles separated from the surface of the mask and contaminants through the exhaust line. In some embodiments, the wind blade slit includes an array of wind blade nozzles spaced apart within the wind blade slit. In some embodiments, the exhausting slit includes array of exhaust lines spaced apart within the exhausting slit.

An photolithographic apparatus includes a particle removing cassette selectively extendable from the processing apparatus. The particle removing cassette includes a wind blade slit and an exhausting slit. The wind blade slit is configured to direct pressurized cleaning material to a surface of the mask to remove the debris particles from the surface of the mask. The exhausting slit collects the debris particles separated from the surface of the mask and contaminants through the exhaust line. In some embodiments, the wind blade slit includes an array of wind blade nozzles spaced apart within the wind blade slit. In some embodiments, the exhausting slit includes array of exhaust lines spaced apart within the exhausting slit.