Abstract: A method for implementing discrete superpositioning of two or more defocal wafer images at different defocal positions in a lithographic step and scan projection system. The method includes tilting one of a mask and a wafer with respect to a scanning direction and splitting an illumination beam into at least two illumination areas which are in different defocus zones of the mask.

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A method and an apparatus for repairing resist latent image on a wafer are disclosed. In the method, an image scanner equipped with a first and a second wafer carrier, and a primary imaging column and a secondary imaging column is utilized to conduct the processes of imaging a resist latent image on a first wafer and repairing a defect in a resist latent image on a second wafer positioned on a second wafer carrier simultaneously. The primary imaging column and the secondary imaging column may be situated in the same vacuum chamber to facilitate operation.

Abstract: A new method is provided for the creation of contact holes. The invention provides two masks. The first mask, referred to as the packed mask, comprises the desired contact holes, which are part of the creation of a semiconductor device. To the packed mask are added padding holes in order to increase the hole density of the packed mask. The second mask, referred to an the unpacking mask, comprises openings at the same locations as the locations of the padding holes of the first mask, the openings provided in the second mask have slightly larger dimensions than the padding holes of the first mask. A first exposure is made using the packed mask, a second exposure of the same surface area is made using the unpacking mask. The unpacking mask is used to selectively cover the padding contact holes, resulting in the final image.

Abstract: A method for transferring a pattern from a mask to a substrate (or wafer), comprises dividing a mask generation data file into a plurality of segments. The segments include a main pattern area and a stitching area. Each stitching area contains a respective common pattern. An image of an illuminated portion of the main pattern area is formed. Connection ends of the segments in a substrate area (or wafer area) are illuminated with an illumination beam. An image of the illuminated portion of the main pattern area is formed, and a halftone gray level dosage distribution is produced in the substrate area (or wafer area) corresponding to the common pattern. The common patterns of adjacent segments substantially overlap in the substrate area (or wafer area).

Abstract: A method for implementing discrete superpositioning of two or more defocal wafer images at different defocal positions in a lithographic step and scan projection system. The method includes tilting one of a mask and a wafer with respect to a scanning direction and splitting an illumination beam into at least two illumination areas which are in different defocus zones of the mask.

Abstract: A new optical lithographic exposure apparatus is described. The apparatus may comprise, for example, a lithographic stepper or scanner. A wafer stage comprises a means of supporting a semiconductor wafer. A mask stage comprises a means of holding a first mask and a second mask and maintaining a fixed relative position between the first mask and the second mask. The mask stage may further comprise an independent means of aligning each mask. A light source comprises a means to selectively shine actinic light through one of the first mask and the second mask. An imaging lens is capable of focusing the actinic light onto the semiconductor wafer.

Abstract: A method and an apparatus for repairing resist latent image on a wafer are disclosed. In the method, an image scanner equipped with a first and a second wafer carrier, and a primary imaging column and a secondary imaging column is utilized to conduct the processes of imaging a resist latent image on a first wafer and repairing a defect in a resist latent image on a second wafer positioned on a second wafer carrier simultaneously. The primary imaging column and the secondary imaging column may be situated in the same vacuum chamber to facilitate operation.

Abstract: A method of inter-field critical dimension control. The method is applied to a wafer with a plurality of dies manufactured by a wafer manufacturing process that includes exposure. According to the method, a plurality of manufacturing modules is obtained by selecting a manufacturing device for each process of the manufacture. Then, for each manufacturing module, exposure is performed with a predetermined exposure energy to obtain critical dimension distribution data corresponding to the predetermined exposure energy, and critical dimension calibration data for each of the dies is further determined. Thus, when one of the manufacturing modules is applied to perform the manufacture, an exposure energy for each of the dies is determined according to the predetermined exposure energy and the critical dimension calibration data for each of the dies, and the manufacture is performed with the exposure energy on each of the dies for the manufacturing module.

Abstract: A method for transferring a pattern from a mask to a substrate (or wafer), comprises dividing a mask generation data file into a plurality of segments. The segments include a main pattern area and a stitching area. Each stitching area contains a respective common pattern. An image of an illuminated portion of the main pattern area is formed. Connection ends of the segments in a substrate area (or wafer area) are illuminated with an illumination beam. An image of the illuminated portion of the main pattern area is formed, and a halftone gray level dosage distribution is produced in the substrate area (or wafer area) corresponding to the common pattern. The common patterns of adjacent segments substantially overlap in the substrate area (or wafer area).

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A new optical lithographic exposure apparatus is described. The apparatus may comprise, for example, a lithographic stepper or scanner. A wafer stage comprises a means of supporting a semiconductor wafer. A mask stage comprises a means of holding a first mask and a second mask and maintaining a fixed relative position between the first mask and the second mask. The mask stage may further comprise an independent means of aligning each mask. A light source comprises a means to selectively shine actinic light through one of the first mask and the second mask. An imaging lens is capable of focusing the actinic light onto the semiconductor wafer. A step and scan method using the mask stage is provided. A first mask and a second mask are loaded into a mask stage of an optical lithographic exposure apparatus. The first mask and the second mask are aligned. The first mask is scanned. The wafer is then stepped. The second mask is scanned.

Abstract: A process is described for shrinking gate lengths and poly interconnects simultaneously during the fabrication of an integrated circuit. A positive tone photoresist is coated on a substrate and is first exposed with an alternating phase shift mask that has full size scattering bars which enable a gate dimension to be printed that is ¼ to ½ the size of the exposing wavelength. The substrate is then exposed using a tritone attenuated phase shift mask with a chrome blocking area to protect the shrunken gates and attenuated areas with scattering bars for shrinking the interconnect lines. Scattering bars are not printed in the photoresist pattern. The process affords higher DOF, lower OPE, and less sensitivity to lens aberrations than conventional lithography methods. A data processing flow is provided which leads to a modified GDS layout for each of the two masks. A system for producing phase shifting layout data is also included.

Abstract: A method of inter-field critical dimension control. The method is applied to a wafer with a plurality of dies manufactured by a wafer manufacturing process that includes exposure. According to the method, a plurality of manufacturing modules is obtained by selecting a manufacturing device for each process of the manufacture. Then, for each manufacturing module, exposure is performed with a predetermined exposure energy to obtain critical dimension distribution data corresponding to the predetermined exposure energy, and critical dimension calibration data for each of the dies is further determined. Thus, when one of the manufacturing modules is applied to perform the manufacture, an exposure energy for each of the dies is determined according to the predetermined exposure energy and the critical dimension calibration data for each of the dies, and the manufacture is performed with the exposure energy on each of the dies for the manufacturing module.

Abstract: A method of producing defect free resist images from defective phase shifting or extreme ultraviolet masks is described. The method uses supplemental radiation to achieve direct repair of the resist image. Pinhole type of defects in opaque pattern elements, which would cause overexposed regions of resist and can readily be repaired on the mask, are first repaired directly on the mask before the mask is used in the exposure of a layer of resist. The remaining defects on the mask are left as they are and not repaired. The layer of resist is then exposed using the partially repaired mask. The remaining mask defects will cause unexposed latent images in the layer of resist. These unexposed regions of the resist are then exposed using supplemental radiation thereby correcting the exposure of the layer of resist. The layer of resist is then developed to form a defect free resist image.

Abstract: A new optical lithographic exposure apparatus is described. The apparatus may comprise, for example, a lithographic stepper or scanner. A wafer stage comprises a means of supporting a semiconductor wafer. A mask stage comprises a means of holding a first mask and a second mask and maintaining a fixed relative position between the first mask and the second mask. The mask stage may further comprise an independent means of aligning each mask. A light source comprises a means to selectively shine actinic light through one of the first mask and the second mask. An imaging lens is capable of focusing the actinic light onto the semiconductor wafer. A step and scan method using the mask stage is provided. A first mask and a second mask are loaded into a mask stage of an optical lithographic exposure apparatus. The first mask and the second mask are aligned. The first mask is scanned. The wafer is then stepped. The second mask is scanned.