Probing Micro-Newton Forces on Solid/Liquid/Gas Interfaces Using Transmission Phase Shift

Xianfu Huang; Huimin Dong; Zhanwei Liu; Ya Pu Zhao

doi:10.1021/acs.langmuir.8b03922

Probing Micro-Newton Forces on Solid/Liquid/Gas Interfaces Using Transmission Phase Shift

Xianfu Huang
, Huimin Dong
, Zhanwei Liu^*
, Ya Pu Zhao^*

^*Corresponding author for this work

School of Aerospace Engineering

CAS - Institute of Mechanics
Beijing Institute of Technology
University of Chinese Academy of Sciences

Research output: Contribution to journal › Article › peer-review

14 Citations (Scopus)

Abstract

Many of the nature and life systems are driven by capillary interactions on solid/liquid/gas interfaces. Here, we present a profilometry technique called transmission phase shift for visualizing the liquid/gas interfaces in three dimensions with high resolution. Using this approach, we probe the change in tiny forces with particle radius at a solid/liquid/gas interface. We provide the first direct evidence that in the issues of floating versus sinking at small-scale, Archimedes' principle should be generalized to include the crucial role of surface tension and reveal the dominant regimes of floating particles based on the Bond number. Remarkably, the measured forces are in the range of micro-Newtons, suggesting that this terse methodology may guide the future design of a liquid microbalance and will be a universal tool for investigating capillarity and interface issues.

Original language	English
Pages (from-to)	5442-5447
Number of pages	6
Journal	Langmuir
Volume	35
Issue number	16
DOIs	https://doi.org/10.1021/acs.langmuir.8b03922
Publication status	Published - 23 Apr 2019

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title = "Probing Micro-Newton Forces on Solid/Liquid/Gas Interfaces Using Transmission Phase Shift",

abstract = "Many of the nature and life systems are driven by capillary interactions on solid/liquid/gas interfaces. Here, we present a profilometry technique called transmission phase shift for visualizing the liquid/gas interfaces in three dimensions with high resolution. Using this approach, we probe the change in tiny forces with particle radius at a solid/liquid/gas interface. We provide the first direct evidence that in the issues of floating versus sinking at small-scale, Archimedes' principle should be generalized to include the crucial role of surface tension and reveal the dominant regimes of floating particles based on the Bond number. Remarkably, the measured forces are in the range of micro-Newtons, suggesting that this terse methodology may guide the future design of a liquid microbalance and will be a universal tool for investigating capillarity and interface issues.",

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Y1 - 2019/4/23

N2 - Many of the nature and life systems are driven by capillary interactions on solid/liquid/gas interfaces. Here, we present a profilometry technique called transmission phase shift for visualizing the liquid/gas interfaces in three dimensions with high resolution. Using this approach, we probe the change in tiny forces with particle radius at a solid/liquid/gas interface. We provide the first direct evidence that in the issues of floating versus sinking at small-scale, Archimedes' principle should be generalized to include the crucial role of surface tension and reveal the dominant regimes of floating particles based on the Bond number. Remarkably, the measured forces are in the range of micro-Newtons, suggesting that this terse methodology may guide the future design of a liquid microbalance and will be a universal tool for investigating capillarity and interface issues.

AB - Many of the nature and life systems are driven by capillary interactions on solid/liquid/gas interfaces. Here, we present a profilometry technique called transmission phase shift for visualizing the liquid/gas interfaces in three dimensions with high resolution. Using this approach, we probe the change in tiny forces with particle radius at a solid/liquid/gas interface. We provide the first direct evidence that in the issues of floating versus sinking at small-scale, Archimedes' principle should be generalized to include the crucial role of surface tension and reveal the dominant regimes of floating particles based on the Bond number. Remarkably, the measured forces are in the range of micro-Newtons, suggesting that this terse methodology may guide the future design of a liquid microbalance and will be a universal tool for investigating capillarity and interface issues.

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Probing Micro-Newton Forces on Solid/Liquid/Gas Interfaces Using Transmission Phase Shift

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