Diffraction-based overlay metrology using angular-multiplexed acquisition of dark-field digital holograms

CHRISTOS MESSINIS; THEODORUS T.M. VAN SCHAIJK; NITESH PANDEY; VASCO T. TENNER; STEFAN WITTE; JOHANNES F. DE BOER; ARIE DEN BOEF

doi:10.1364/OE.413020

Diffraction-based overlay metrology using angular-multiplexed acquisition of dark-field digital holograms

CHRISTOS MESSINIS^*
, THEODORUS T.M. VAN SCHAIJK
, NITESH PANDEY
, VASCO T. TENNER
, STEFAN WITTE
, JOHANNES F. DE BOER
, ARIE DEN BOEF

^*Corresponding author for this work

Research output: Contribution to Journal › Article › Academic › peer-review

Abstract

In semiconductor device manufacturing, optical overlay metrology measures pattern placement between two layers in a chip with sub-nm precision. Continuous improvements in overlay metrology are needed to keep up with shrinking device dimensions in modern chips. We present first overlay metrology results using a novel off-axis dark-field digital holographic microscopy concept that acquires multiple holograms in parallel by angular multiplexing. We show that this concept reduces the impact of source intensity fluctuations on the noise in the measured overlay. With our setup we achieved an overlay reproducibility of 0.13 nm and measurements on overlay targets with known programmed overlay values showed good linearity of R2= 0.9993. Our data show potential for significant improvement and that digital holographic microscopy is a promising technique for future overlay metrology tools.

Original language	English
Pages (from-to)	37419-37435
Number of pages	17
Journal	Optics Express
Volume	28
Issue number	25
Early online date	24 Nov 2020
DOIs	https://doi.org/10.1364/OE.413020
Publication status	Published - 7 Dec 2020

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title = "Diffraction-based overlay metrology using angular-multiplexed acquisition of dark-field digital holograms",

abstract = "In semiconductor device manufacturing, optical overlay metrology measures pattern placement between two layers in a chip with sub-nm precision. Continuous improvements in overlay metrology are needed to keep up with shrinking device dimensions in modern chips. We present first overlay metrology results using a novel off-axis dark-field digital holographic microscopy concept that acquires multiple holograms in parallel by angular multiplexing. We show that this concept reduces the impact of source intensity fluctuations on the noise in the measured overlay. With our setup we achieved an overlay reproducibility of 0.13 nm and measurements on overlay targets with known programmed overlay values showed good linearity of R2= 0.9993. Our data show potential for significant improvement and that digital holographic microscopy is a promising technique for future overlay metrology tools.",

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month = dec,

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doi = "10.1364/OE.413020",

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AU - MESSINIS, CHRISTOS

AU - VAN SCHAIJK, THEODORUS T.M.

AU - PANDEY, NITESH

AU - TENNER, VASCO T.

AU - WITTE, STEFAN

AU - DE BOER, JOHANNES F.

AU - BOEF, ARIE DEN

PY - 2020/12/7

Y1 - 2020/12/7

N2 - In semiconductor device manufacturing, optical overlay metrology measures pattern placement between two layers in a chip with sub-nm precision. Continuous improvements in overlay metrology are needed to keep up with shrinking device dimensions in modern chips. We present first overlay metrology results using a novel off-axis dark-field digital holographic microscopy concept that acquires multiple holograms in parallel by angular multiplexing. We show that this concept reduces the impact of source intensity fluctuations on the noise in the measured overlay. With our setup we achieved an overlay reproducibility of 0.13 nm and measurements on overlay targets with known programmed overlay values showed good linearity of R2= 0.9993. Our data show potential for significant improvement and that digital holographic microscopy is a promising technique for future overlay metrology tools.

AB - In semiconductor device manufacturing, optical overlay metrology measures pattern placement between two layers in a chip with sub-nm precision. Continuous improvements in overlay metrology are needed to keep up with shrinking device dimensions in modern chips. We present first overlay metrology results using a novel off-axis dark-field digital holographic microscopy concept that acquires multiple holograms in parallel by angular multiplexing. We show that this concept reduces the impact of source intensity fluctuations on the noise in the measured overlay. With our setup we achieved an overlay reproducibility of 0.13 nm and measurements on overlay targets with known programmed overlay values showed good linearity of R2= 0.9993. Our data show potential for significant improvement and that digital holographic microscopy is a promising technique for future overlay metrology tools.

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Diffraction-based overlay metrology using angular-multiplexed acquisition of dark-field digital holograms

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