Abstract: A method includes receiving a substrate having a material feature embedded in the substrate, wherein receiving the substrate includes receiving a first leveling data and a first overlay data generated when forming the material feature, deposing a resist film on the substrate, and exposing the resist film using a predicted overlay correction data to form a resist pattern overlying the material feature on the substrate, wherein using the predicted overlay correction data includes generating a second leveling data and calculating the predicted overlay correction data using the first leveling data, the first overlay data, and the second leveling data.

Abstract: A method includes directing a beam of radiation along an optical axis toward a workpiece support, measuring a spectrum of the beam at a first time to obtain a first profile, measuring the spectrum of the beam at a second time to obtain a second profile, determining a spectral difference between the two profiles, and adjusting a position of the workpiece support along the optical axis based on the difference. A different aspect involves an apparatus having a workpiece support, beam directing structure that directs a beam of radiation along an optical axis toward the workpiece support, spectrum measuring structure that measures a spectrum of the beam at first and second times to obtain respective first and second profiles, processing structure that determines a difference between the two profiles, and support adjusting structure that adjusts a position of the workpiece support along the optical axis based on the difference.

Abstract: A method includes directing a beam of radiation along an optical axis toward a workpiece support, measuring a spectrum of the beam at a first time to obtain a first profile, measuring the spectrum of the beam at a second time to obtain a second profile, determining a spectral difference between the two profiles, and adjusting a position of the workpiece support along the optical axis based on the difference. A different aspect involves an apparatus having a workpiece support, beam directing structure that directs a beam of radiation along an optical axis toward the workpiece support, spectrum measuring structure that measures a spectrum of the beam at first and second times to obtain respective first and second profiles, processing structure that determines a difference between the two profiles, and support adjusting structure that adjusts a position of the workpiece support along the optical axis based on the difference.

Abstract: A method includes receiving a substrate having a material feature embedded in the substrate, wherein receiving the substrate includes receiving a first leveling data and a first overlay data generated when forming the material feature, deposing a resist film on the substrate, and exposing the resist film using a predicted overlay correction data to form a resist pattern overlying the material feature on the substrate, wherein using the predicted overlay correction data includes generating a second leveling data and calculating the predicted overlay correction data using the first leveling data, the first overlay data, and the second leveling data.

Abstract: A method includes directing a beam of radiation along an optical axis toward a workpiece support, measuring a spectrum of the beam at a first time to obtain a first profile, measuring the spectrum of the beam at a second time to obtain a second profile, determining a spectral difference between the two profiles, and adjusting a position of the workpiece support along the optical axis based on the difference. A different aspect involves an apparatus having a workpiece support, beam directing structure that directs a beam of radiation along an optical axis toward the workpiece support, spectrum measuring structure that measures a spectrum of the beam at first and second times to obtain respective first and second profiles, processing structure that determines a difference between the two profiles, and support adjusting structure that adjusts a position of the workpiece support along the optical axis based on the difference.

Abstract: Provided is an apparatus that includes an overlay mark. The overlay mark includes a first portion that includes a plurality of first features. Each of the first features have a first dimension measured in a first direction and a second dimension measured in a second direction that is approximately perpendicular to the first direction. The second dimension is greater than the first dimension. The overlay mark also includes a second portion that includes a plurality of second features. Each of the second features have a third dimension measured in the first direction and a fourth dimension measured in the second direction. The fourth dimension is less than the third dimension. At least one of the second features is partially surrounded by the plurality of first features in both the first and second directions.

Abstract: Disclosed is a lithography system. The lithography system includes a lithography exposure tool designed for performing an exposure process to a radiation-sensitive material layer coated on an integrated circuit substrate; an alignment module coupled with the lithography exposure tool, designed for alignment measurement, and configured for transferring the integrated circuit substrate to the lithography exposure tool; and an alignment calibration module designed to calibrate the alignment module relative to the lithography exposure.

Abstract: A method includes directing a beam of radiation along an optical axis toward a workpiece support, measuring a spectrum of the beam at a first time to obtain a first profile, measuring the spectrum of the beam at a second time to obtain a second profile, determining a spectral difference between the two profiles, and adjusting a position of the workpiece support along the optical axis based on the difference. A different aspect involves an apparatus having a workpiece support, beam directing structure that directs a beam of radiation along an optical axis toward the workpiece support, spectrum measuring structure that measures a spectrum of the beam at first and second times to obtain respective first and second profiles, processing structure that determines a difference between the two profiles, and support adjusting structure that adjusts a position of the workpiece support along the optical axis based on the difference.

Abstract: Provided is an apparatus that includes an overlay mark. The overlay mark includes a first portion that includes a plurality of first features. Each of the first features have a first dimension measured in a first direction and a second dimension measured in a second direction that is approximately perpendicular to the first direction. The second dimension is greater than the first dimension. The overlay mark also includes a second portion that includes a plurality of second features. Each of the second features have a third dimension measured in the first direction and a fourth dimension measured in the second direction. The fourth dimension is less than the third dimension. At least one of the second features is partially surrounded by the plurality of first features in both the first and second directions.

Abstract: A method includes directing a beam of radiation along an optical axis toward a workpiece support, measuring a spectrum of the beam at a first time to obtain a first profile, measuring the spectrum of the beam at a second time to obtain a second profile, determining a spectral difference between the two profiles, and adjusting a position of the workpiece support along the optical axis based on the difference. A different aspect involves an apparatus having a workpiece support, beam directing structure that directs a beam of radiation along an optical axis toward the workpiece support, spectrum measuring structure that measures a spectrum of the beam at first and second times to obtain respective first and second profiles, processing structure that determines a difference between the two profiles, and support adjusting structure that adjusts a position of the workpiece support along the optical axis based on the difference.

Abstract: Provided is an apparatus that includes an overlay mark. The overlay mark includes a first portion that includes a plurality of first features. Each of the first features have a first dimension measured in a first direction and a second dimension measured in a second direction that is approximately perpendicular to the first direction. The second dimension is greater than the first dimension. The overlay mark also includes a second portion that includes a plurality of second features. Each of the second features have a third dimension measured in the first direction and a fourth dimension measured in the second direction. The fourth dimension is less than the third dimension. At least one of the second features is partially surrounded by the plurality of first features in both the first and second directions.

Abstract: A photolithography system for printing a pattern of at least one contact or via on a wafer is provided. The system comprises a reticle having a layout, the layout comprises at least one polygon-shaped hole, wherein the at least one polygon-shaped hole comprises at least eight sides.

Abstract: A method for photolithography in semiconductor manufacturing includes providing a substrate for a wafer and providing a mask for exposing the wafer. The wafer is exposed by utilizing a combination of high angle illumination and focus drift exposure methods.

Abstract: A lithography apparatus includes an imaging lens module; a substrate table positioned underlying the imaging lens module and configured to hold a substrate; a fluid retaining module configured to hold a fluid in a space between the imaging lens module and a substrate on the substrate stage; and a heating element configured in the fluid retaining module and adjacent to the space. The heating element includes at least two of following: a sealant insoluble to the fluid for sealing the heating element in the fluid retaining module; a sealed opening configured in one of top portion and side portion of the fluid retaining module for sealing the heating element in the fluid retaining module; and/or a non-uniform temperature compensation device configured with the heating element.

Abstract: A lithography process to pattern a plurality of fields on a substrate is disclosed. The process includes scanning a first field along a first direction using a radiation beam. Thereafter, the processes steps to a second field adjacent the first field and located behind the first field when the first and second fields are viewed along the first direction. The second field is then scanned along the first direction using the radiation beam.

Abstract: A photolithography system for printing a pattern of at least one contact or via on a wafer is provided. The system comprises a reticle having a layout, the layout comprises at least one polygon-shaped hole, wherein the at least one polygon-shaped hole comprises at least eight sides.

Abstract: A method for photolithography processing includes providing a substrate coated with a photosensitive layer thereon and a top coater overlying the photosensitive layer; exposing the photosensitive layer to a radiation energy; removing the top coater; and baking the photosensitive layer after the removing of the top coater layer.

Abstract: A lithography process to pattern a plurality of fields on a substrate is disclosed. The process includes scanning a first field along a first direction using a radiation beam. Thereafter, the processes steps to a second field adjacent the first field and located behind the first field when the first and second fields are viewed along the first direction. The second field is then scanned along the first direction using the radiation beam.

Abstract: A lithography apparatus includes an imaging lens module; a substrate table positioned underlying the imaging lens module and configured to hold a substrate; a fluid retaining module configured to hold a fluid in a space between the imaging lens module and a substrate on the substrate stage; and a heating element configured in the fluid retaining module and adjacent to the space. The heating element includes at least one of following: a sealant insoluble to the fluid for sealing the heating element in the fluid retaining module; a sealed opening configured in one of top portion and side portion of the fluid retaining module for sealing the heating element in the fluid retaining module; and/or a non-uniform temperature compensation device configured with the heating element.

Abstract: A method for photolithography in semiconductor manufacturing includes providing a substrate for a wafer and providing a mask for exposing the wafer. The wafer is exposed by utilizing a combination of high angle illumination and focus drift exposure methods.