Detection and repair of multiphase defects on alternating phase-shift masks for DUV lithography

Nagashige, Susumu; Hayashi, Koki; Akima, Shinji; Takahashi, Hiroyuki; Chiba, Kazuaki; Yamada, Yoshiro; Matsuzawa, Yuichi

doi:10.1117/12.373308

Cited by 6 publications

(1 citation statement)

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“…2 Dimensional simulation was compared to 3 Dimensional Electro-Magnetic Field simulation for the printability of phase bump defects and divot defects. 4. Based on verified defect simulation for '-4 :3 duty ratio test patterns, printable phase defects for denser pattern were predicted.…”

Section: Introductionmentioning

confidence: 99%

<title>Alternating PSM phase defect printability for 100-nm KrF lithography</title>

Kim

Gordon

et al. 2000

SPIE Proceedings

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Optical lithography is pushed more to extend to sub-wavelength region for very low ki patterning processes; in which, alternating PSM is the solution for isolated patterns, without changing the wavelength of exposure tools' light source. With this prospect, the critical issues such as design layout complexity, light intensity imbalance between shifted and unshifted space area, and phase defect controllability have recently been studied in order to apply alternating PSM for device mass production.In this paper, we studied to find out the maximum non-printable phase defects for l3Onm and lOOnm lines by printing the wafer using a KrF DUV scanner. With the limitations of the mask making process for very small programmed defects, we made the masks with duty ratio around 1 :3. After we verified the resist simulation for our test pattern by wafer printing results, printable defects for denser pattern were predicted.In addition to defect printability study, the mechanical repair tool for phase bump defects was tested using 248nm AIMS, AFM, and CD SEM metrology as well as wafer printing. Electromagnetic Field 3 dimension simulation was also compared with commercialized 2D simulation tool for phase defect printability.

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Section: Introductionmentioning

confidence: 99%