Abstract: An exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas includes: a main exhaust pipe above the semiconductor manufacturing equipment and having a top surface on a first side and a bottom surface on a second side, a first branch pipe connected to a source of a gas mixture containing the hazardous gas on the second side and connected to the main exhaust pipe through the top surface, a second branch pipe connected to a gas box on the second side and connected to the main exhaust pipe through the bottom surface, and a detector on the second branch pipe configured to detect presence of the hazardous gas and downstream to the gas box. The first and the second branch pipes are connected to the main exhaust pipe at a first location and a second location, respectively. The first location is more upstream than the second location.

Abstract: A lithography mask includes a substrate that contains a low thermal expansion material (LTEM). The lithography mask also includes a reflective structure disposed over the substrate. The reflective structure includes a first layer and a second layer disposed over the first layer. At least the second layer is porous. The mask is formed by forming a multilayer reflective structure over the LTEM substrate, including forming a plurality of repeating film pairs, where each film pair includes a first layer and a porous second layer. A capping layer is formed over the multilayer reflective structure. An absorber layer is formed over the capping layer.

Abstract: An exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas includes: a main exhaust pipe above the semiconductor manufacturing equipment and having a top surface on a first side and a bottom surface on a second side, a first branch pipe connected to a source of a gas mixture containing the hazardous gas on the second side and connected to the main exhaust pipe through the top surface, a second branch pipe connected to a gas box on the second side and connected to the main exhaust pipe through the bottom surface, and a detector on the second branch pipe configured to detect presence of the hazardous gas and downstream to the gas box. The first and the second branch pipes are connected to the main exhaust pipe at a first location and a second location, respectively. The first location is more upstream than the second location.

Abstract: The present disclosure provides an exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas. The exhaust system includes: a main exhaust pipe positioned above the semiconductor manufacturing equipment and having a top surface and a bottom surface extending parallel to the top surface; a first branch pipe including an upstream end coupled to a source of a gas mixture and a downstream end connected to the main exhaust pipe through the top surface; a second branch pipe including an upstream end and a downstream end connected to the main exhaust pipe through the bottom surface; and a detector configured to detect presence of the hazardous gas in the second branch pipe.

Abstract: A lithography mask includes a substrate that contains a low thermal expansion material (LTEM). The lithography mask also includes a reflective structure disposed over the substrate. The reflective structure includes a first layer and a second layer disposed over the first layer. At least the second layer is porous. The mask is formed by forming a multilayer reflective structure over the LTEM substrate, including forming a plurality of repeating film pairs, where each film pair includes a first layer and a porous second layer. A capping layer is formed over the multilayer reflective structure. An absorber layer is formed over the capping layer.

Abstract: A lithography mask includes a substrate that contains a low thermal expansion material (LTEM). The lithography mask also includes a reflective structure disposed over the substrate. The reflective structure includes a first layer and a second layer disposed over the first layer. At least the second layer is porous. The mask is formed by forming a multilayer reflective structure over the LTEM substrate, including forming a plurality of repeating film pairs, where each film pair includes a first layer and a porous second layer. A capping layer is formed over the multilayer reflective structure. An absorber layer is formed over the capping layer.

Abstract: The present disclosure provides an exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas. The exhaust system includes: a main exhaust pipe positioned above the semiconductor manufacturing equipment and having a top surface and a bottom surface extending parallel to the top surface; a first branch pipe including an upstream end coupled to a source of a gas mixture and a downstream end connected to the main exhaust pipe through the top surface; a second branch pipe including an upstream end and a downstream end connected to the main exhaust pipe through the bottom surface; and a detector configured to detect presence of the hazardous gas in the second branch pipe.

Abstract: The present disclosure provides an exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas. The exhaust system includes: a main exhaust pipe having a top surface and a bottom surface; a first branch pipe including an upstream end coupled to a source of a gas mixture containing the hazardous gas and a downstream end connected to the main exhaust pipe through the top surface; a second branch pipe including a downstream end connected to the main exhaust pipe through the bottom surface; and a detector configured to detect presence of the hazardous gas in the second branch pipe.

Abstract: A method of inspecting a reticle includes obtaining a first image of a surface of the reticle at a first height by scanning the reticle surface with a light source at the first height of the reticle surface relative to a reference surface height of the reticle surface and obtaining a second image of the reticle surface at a second height by scanning the reticle surface with the light source at the second height of the reticle surface relative to the reference surface height of the reticle surface. The second height is different from the first height. The first and the second images are then combined to obtain a surface profile image of the reticle.

Abstract: A lithography mask includes a substrate that contains a low thermal expansion material (LTEM). The lithography mask also includes a reflective structure disposed over the substrate. The reflective structure includes a first layer and a second layer disposed over the first layer. At least the second layer is porous. The mask is formed by forming a multilayer reflective structure over the LTEM substrate, including forming a plurality of repeating film pairs, where each film pair includes a first layer and a porous second layer. A capping layer is formed over the multilayer reflective structure. An absorber layer is formed over the capping layer.

Abstract: A method of inspecting a reticle includes obtaining a first image of a surface of the reticle at a first height by scanning the reticle surface with a light source at the first height of the reticle surface relative to a reference surface height of the reticle surface and obtaining a second image of the reticle surface at a second height by scanning the reticle surface with the light source at the second height of the reticle surface relative to the reference surface height of the reticle surface. The second height is different from the first height. The first and the second images are then combined to obtain a surface profile image of the reticle.

Abstract: A lithography mask includes a substrate that contains a low thermal expansion material (LTEM). The lithography mask also includes a reflective structure disposed over the substrate. The reflective structure includes a first layer and a second layer disposed over the first layer. At least the second layer is porous. The mask is formed by forming a multilayer reflective structure over the LTEM substrate, including forming a plurality of repeating film pairs, where each film pair includes a first layer and a porous second layer. A capping layer is formed over the multilayer reflective structure. An absorber layer is formed over the capping layer.

Abstract: The present disclosure provides an exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas. The exhaust system includes: a main exhaust pipe having a top surface and a bottom surface; a first branch pipe including an upstream end coupled to a source of a gas mixture containing the hazardous gas and a downstream end connected to the main exhaust pipe through the top surface; a second branch pipe including a downstream end connected to the main exhaust pipe through the bottom surface; and a detector configured to detect presence of the hazardous gas in the second branch pipe.

Abstract: A method of inspecting a reticle includes obtaining a first image of a surface of the reticle at a first height by scanning the reticle surface with a light source at the first height of the reticle surface relative to a reference surface height of the reticle surface and obtaining a second image of the reticle surface at a second height by scanning the reticle surface with the light source at the second height of the reticle surface relative to the reference surface height of the reticle surface. The second height is different from the first height. The first and the second images are then combined to obtain a surface profile image of the reticle.

Abstract: The present disclosure provides an exhaust system for discharging from semiconductor manufacturing equipment a hazardous gas. The exhaust system includes: a main exhaust pipe having a top surface and a bottom surface; a first branch pipe including an upstream end coupled to a source of a gas mixture containing the hazardous gas and a downstream end connected to the main exhaust pipe through the top surface; a second branch pipe including a downstream end connected to the main exhaust pipe through the bottom surface; and a detector configured to detect presence of the hazardous gas in the second branch pipe.

Abstract: Embodiments described herein provide a method for cleaning contamination from sensors in a lithography tool without requiring recalibrating the lithography tool. More particularly, embodiments described herein teach cleaning the sensors using hydrogen radicals for a short period while the performance drifting is still above the drift tolerance. After a cleaning process described herein, the lithography tool can resume production without recalibration.

Abstract: Embodiments described herein provide a method for cleaning contamination from sensors in a lithography tool without requiring recalibrating the lithography tool. More particularly, embodiments described herein teach cleaning the sensors using hydrogen radicals for a short period while the performance drifting is still above the drift tolerance. After a cleaning process described herein, the lithography tool can resume production without recalibration.

Abstract: Embodiments described herein provide a method for cleaning contamination from sensors in a lithography tool without requiring recalibrating the lithography tool. More particularly, embodiments described herein teach cleaning the sensors using hydrogen radicals for a short period while the performance drifting is still above the drift tolerance. After a cleaning process described herein, the lithography tool can resume production without recalibration.

Abstract: Embodiments described herein provide a method for cleaning contamination from sensors in a lithography tool without requiring recalibrating the lithography tool. More particularly, embodiments described herein teach cleaning the sensors using hydrogen radicals for a short period while the performance drifting is still above the drift tolerance. After a cleaning process described herein, the lithography tool can resume production without recalibration.

Abstract: A method of inspecting a reticle includes obtaining a first image of a surface of the reticle at a first height by scanning the reticle surface with a light source at the first height of the reticle surface relative to a reference surface height of the reticle surface and obtaining a second image of the reticle surface at a second height by scanning the reticle surface with the light source at the second height of the reticle surface relative to the reference surface height of the reticle surface. The second height is different from the first height. The first and the second images are then combined to obtain a surface profile image of the reticle.