Abstract: An apparatus for reducing hydrogen permeation of a mask is provided when generating extreme ultraviolet (EUV) radiation. The apparatus includes a mask stage configured to hold the mask, a hydrogen dispensing nozzle configured to eject hydrogen below the mask, and a trajectory correcting assembly. The trajectory correcting assembly includes a correcting nozzle and a gas flow detector. The correcting nozzle is configured to dispense at least one flow adjusting gas to adjust a trajectory of the hydrogen away from the mask to reduce hydrogen permeation at an edge of the mask. The gas flow detector is configured to measure a variation of an airflow of the hydrogen adjusted by the at least one flow adjusting gas.

Abstract: A method includes holding a mask using an electrostatic chuck. The mask includes a substrate having a first bump and a second bump separated from the first bump and a patterned layer. The first bump and the second bump face the electrostatic chuck. The substrate is between the patterned layer and the electrostatic chuck. The first bump and the second bump are spaced apart from the patterned layer. The first bump and the second bump are ring strips in a top view, and the first bump has a rectangular cross section and the second bump has a triangular cross section. The method further includes generating extreme ultraviolet (EUV) radiation using an EUV light source; and directing the EUV radiation toward the mask, such that the EUV radiation is reflected by the mask.

Abstract: A photolithography method includes dispensing a first liquid onto a first target layer formed over a first wafer through a nozzle at a first distance from the first target layer; capturing an image of the first liquid on the first target layer; patterning the first target layer after capturing the image of the first liquid; comparing the captured image of the first liquid to a first reference image to generate a first comparison result; responsive to the first comparison result, positioning the nozzle and a second wafer such that the nozzle is at a second distance from a second target layer on the second wafer; dispensing a second liquid onto the second target layer formed over the second wafer through the nozzle at the second distance from the second target layer; and patterning the second target layer after dispensing the second liquid.

Abstract: A method includes transmitting a radiation toward an electrostatic chuck, receiving a reflection of the radiation, analyzing the reflection of the radiation, determining whether a particle is present on the electrostatic chuck based on the analyzing the reflection of the radiation, and moving a cleaning tool to a location of the particle on the electrostatic chuck when the determination determines that the particle is present.

Abstract: Embodiments described herein provide a lithographic system having two or more lithographic tools connected to a radiation source using two or more variable attenuation units. In some embodiments, the variable attenuation unit reflects a portion of the received light beam to the lithographic tool attached thereto and transmits a remaining portion of the received light beam to the lithographic tools downstream. In some embodiments, the radiation source includes two or more laser sources to provide laser beams with an enhanced power level and which can prevent operation interruption due to laser source maintenances and repair.

Abstract: A lithography system includes a collector having a mirror surface, a laser generator aiming at an excitation zone in front of the mirror surface of the collector, a droplet generator, and a droplet deflector operative to apply a force at a position between the droplet generator and the excitation zone.

Abstract: Embodiments of the present disclosure provide a substrate measuring device in a lithography projection apparatus that provides multiple light sources having different wavelengths. In some embodiments, a lithography projection apparatus includes a substrate measuring system disposed proximate to a substrate stage, the substrate measuring system further including an emitter including multiple light sources configured to provide multiple beams of light, each of at least some of the multiple beams of light having a different wavelength, at least one optical fiber, wherein each of respective portions of the at least one optical fiber is configured to pass a respective one of the multiple beams of light, and a receiver positioned to collected light emitted from the emitter and reflected off of a substrate disposed on the substrate stage.

Abstract: A scanner includes a light source configured to apply a light to a backside of a wafer. The light is reflected from the backside of the wafer. A first mirror is configured to receive the light from the backside of the wafer and reflect the light. A sensor is configured to receive the light from the first mirror and generate an output signal indicative of a backside topography of the wafer.

Abstract: A mask includes a substrate, a light-reflecting structure, a patterned layer, and a plurality of bumps. The substrate has a first surface and a second surface. The light-reflecting structure is located on the first surface of the substrate. The patterned layer is located on the light-reflecting structure. The bumps are located on the second surface of the substrate. The bumps define a plurality of voids therebetween and protrude in a direction away from the second surface of the substrate.

Abstract: A method is described. The method includes obtaining a relationship between a thickness of a contamination layer formed on a mask and an amount of compensation energy to remove the contamination layer, obtaining a first thickness of a first contamination layer formed on the mask from a thickness measuring device, and applying first compensation energy calculated from the relationship to a light directed to the mask.

Abstract: Embodiments described herein provide a lithographic system having two or more lithographic tools connected to a radiation source using two or more variable attenuation units. In some embodiments, the variable attenuation unit reflects a portion of the received light beam to the lithographic tool attached thereto and transmits a remaining portion of the received light beam to the lithographic tools downstream. In some embodiments, the radiation source includes two or more laser sources to provide laser beams with an enhanced power level and which can prevent operation interruption due to laser source maintenances and repair.

Abstract: Embodiments of the present disclosure provide a substrate measuring device in a lithography projection apparatus that provides multiple light sources having different wavelengths. In some embodiments, a lithography projection apparatus includes a substrate measuring system disposed proximate to a substrate stage, the substrate measuring system further including an emitter including multiple light sources configured to provide multiple beams of light, each of at least some of the multiple beams of light having a different wavelength, at least one optical fiber, wherein each of respective portions of the at least one optical fiber is configured to pass a respective one of the multiple beams of light, and a receiver positioned to collected light emitted from the emitter and reflected off of a substrate disposed on the substrate stage.

Abstract: Embodiments of the present disclosure provide methods for processing a substrate using a measuring device in a lithography projection apparatus that provides multiple light sources having different wavelengths. In some embodiments, a lithography projection apparatus includes a substrate measuring system disposed proximate to a substrate stage, the substrate measuring system further including an emitter including multiple light sources configured to provide multiple beams of light, each of at least some of the multiple beams of light having a different wavelength, at least one optical fiber, wherein each of respective zones of the at least one optical fiber is configured to pass a respective one of the multiple beams of light, and a receiver positioned to collected light emitted from the emitter and reflected off of a substrate disposed on the substrate stage.

Abstract: A scanner includes a light source configured to apply a light to a backside of a wafer. The light is reflected from the backside of the wafer. A first mirror is configured to receive the light from the backside of the wafer and reflect the light. A sensor is configured to receive the light from the first mirror and generate an output signal indicative of a backside topography of the wafer.

Abstract: A semiconductor processing method includes operations. An exposure process is performed on a semiconductor workpiece and includes selecting a target state of a reticle based on given data and regulating the reticle to reach the target state. A development process is performed on the semiconductor workpiece.

Abstract: A lithography method in semiconductor fabrication is provided. The method includes generating a plurality of drops of a target material through a plurality of nozzles, adjacent two of the plurality of nozzles having a distance less than a width of a first one of the adjacent two of the plurality of nozzles, wherein the plurality of drops are aggregated to an elongated droplet; generating a laser pulse to convert the elongated droplet into plasma that generates an extreme ultraviolet (EUV) radiation; exposing a semiconductor substrate to the EUV radiation.

Abstract: A method for fabricating a wafer includes providing a wafer table, wherein the wafer table includes support pins that are movable with respect to each other; identifying features of a layer to be formed on a wafer, wherein the features have a tolerance for overlay errors below a threshold; moving one or more support pins based on the features; after the moving of the one or more support pins, mounting the wafer on the wafer table; and after the mounting of the wafer on the wafer table, forming the layer on the wafer.

Abstract: Embodiments of the present disclosure provide a system and method for stabilizing optical lens temperatures, including detecting infrared radiation emitted from one or more optical lens, generating an infrared sensor signal based upon the detected infrared radiation, directing emission of light from one or more infrared light sources to the one or more optical lenses, and regulating the emission of the light from the one or more infrared light sources based on the infrared sensor signal for adjusting the temperature of the one or more optical lens.

Abstract: A system includes a frame, a projection lens, a wafer table, and a cleaner. The frame has an opening vertically extending through the frame. The projection lens is disposed on the frame. The wafer table is below the frame, in which the wafer table is movable along a horizontal direction. The cleaner is over the frame, in which the cleaner comprises a sticky structure movable along a vertical direction and through the opening of the frame.

Abstract: A method for removing particles from a semiconductor process chamber including at least the following steps is provided. Electrical charges having a first polarity are accumulated on a receiving surface of the substrate holder by applying a voltage to the substrate holder. The particles having a second polarity in the semiconductor process chamber are attracted to move toward the receiving surface of the substrate holder on which the electrical charges having the first polarity are accumulated, where the first polarity is opposite to the second polarity. The particles having the second polarity are removed from the semiconductor process chamber. Other methods for removing particles from a semiconductor process chamber are also provided.