Springer Science and Business Media LLC
Microfluidic QCM enables ultrahigh Q-factor: a new paradigm for in-liquid gravimetric sensing
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, Preprint
Zauscher, S; ZHAO, Y; Parlak, Z; Yu, W; French, D; Aquino, W
January 5, 2024
Duke Scholars
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APA
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Zauscher, S., ZHAO, Y., Parlak, Z., Yu, W., French, D., & Aquino, W. (2024). Microfluidic QCM enables ultrahigh Q-factor: a new paradigm for in-liquid gravimetric sensing. Springer Science and Business Media LLC. https://doi.org/10.21203/rs.3.rs-3773425/v1
Zauscher, Stefan, Y. I. C. H. E. N. G. ZHAO, Zehra Parlak, Wenjun Yu, Daniel French, and Wilkins Aquino. “Microfluidic QCM enables ultrahigh Q-factor: a new paradigm for in-liquid gravimetric sensing.” Springer Science and Business Media LLC, January 5, 2024. https://doi.org/10.21203/rs.3.rs-3773425/v1.
Zauscher S, ZHAO Y, Parlak Z, Yu W, French D, Aquino W. Microfluidic QCM enables ultrahigh Q-factor: a new paradigm for in-liquid gravimetric sensing. Springer Science and Business Media LLC. 2024.
Zauscher, Stefan, et al. “Microfluidic QCM enables ultrahigh Q-factor: a new paradigm for in-liquid gravimetric sensing.” Springer Science and Business Media LLC, 5 Jan. 2024. Crossref, doi:10.21203/rs.3.rs-3773425/v1.
Zauscher S, ZHAO Y, Parlak Z, Yu W, French D, Aquino W. Microfluidic QCM enables ultrahigh Q-factor: a new paradigm for in-liquid gravimetric sensing. Springer Science and Business Media LLC. 2024.