A Micro Racetrack Optical Resonator Test Structure to Optimize Pattern Approximation in Direct Lithography Technologies

A Micro Racetrack Optical Resonator Test Structure to Optimize Pattern Approximation in Direct Lithography Technologies

High-throughput electron beam (EB) lithography technologies such as variable shape beam (VSB) and character projection (CP) are drawing much interests to the industries due to the wafer scale exposure capability and reduced exposure time in the order of magnitude. However, the tradeoff relationship...

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Bibliographic Details
Published in:2019 IEEE 32nd International Conference on Microelectronic Test Structures (ICMTS) pp. 4 - 7
Main Authors: Higo, Akio, Sawamura, Tomoki, Fujiwara, Makoto, Ota, Etsuko, Mizushima, Ayako, Lebrasseur, Eric, Arakawa, Taro, Mita, Yoshio
Format: Conference Proceeding
Language:English
Published: IEEE 01-03-2019
Subjects:
character projection
electron beam lithography
Optical fibers
Optical filters
Optical resonators
racetrack resonator
Shape
Silicon
silicon photonics
variable-shaped beam
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Summary:High-throughput electron beam (EB) lithography technologies such as variable shape beam (VSB) and character projection (CP) are drawing much interests to the industries due to the wafer scale exposure capability and reduced exposure time in the order of magnitude. However, the tradeoff relationship of the exposure quality according to the EB exposure pattern approximation methods has not yet been comprehensively studied. The study is essential for photonics because target patterns include curved shapes. We propose a test structure of silicon racetrack resonator to quantify the quality dependence. Three approximation techniques were tried such as octagon shape CP, tilted square CPs, and thin variable shape rectangles. Optical measurement clearly revealed quality differences between methods, which were impossible to be identified by classical metrological methods including Surface Probe Microscopy (SPM).
ISBN:9781728114644
1728114640
ISSN:1071-9032
2158-1029
DOI:10.1109/ICMTS.2019.8730981