Liquid flow along a solid surface reversibly alters interfacial chemistry

Dan Lis; Ellen Backus H. G.; Johannes Hunger; Sapun Parekh H.; Mischa Bonn

doi:10.1126/science.1253793

Liquid flow along a solid surface reversibly alters interfacial chemistry

Dan Lis, Ellen Backus H. G., Johannes Hunger, Sapun Parekh H. , Mischa Bonn

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

Abstract

n nature, aqueous solutions often move collectively along solid surfaces (for example, raindrops falling on the ground and rivers flowing through riverbeds). However, the influence of such motion on water-surface interfacial chemistry is unclear. In this work, we combine surface-specific sum frequency generation spectroscopy and microfluidics to show that at immersed calcium fluoride and fused silica surfaces, flow leads to a reversible modification of the surface charge and subsequent realignment of the interfacial water molecules. Obtaining equivalent effects under static conditions requires a substantial change in bulk solution pH (up to 2 pH units), demonstrating the coupling between flow and chemistry. These marked flow-induced variations in interfacial chemistry should substantially affect our understanding and modeling of chemical processes at immersed surfaces.

Original language	English
Pages (from-to)	1138-1142
Journal	Science
Volume	344
Issue number	6188
DOIs	https://doi.org/10.1126/science.1253793
Publication status	Published - 6 Jun 2014

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title = "Liquid flow along a solid surface reversibly alters interfacial chemistry",

abstract = "n nature, aqueous solutions often move collectively along solid surfaces (for example, raindrops falling on the ground and rivers flowing through riverbeds). However, the influence of such motion on water-surface interfacial chemistry is unclear. In this work, we combine surface-specific sum frequency generation spectroscopy and microfluidics to show that at immersed calcium fluoride and fused silica surfaces, flow leads to a reversible modification of the surface charge and subsequent realignment of the interfacial water molecules. Obtaining equivalent effects under static conditions requires a substantial change in bulk solution pH (up to 2 pH units), demonstrating the coupling between flow and chemistry. These marked flow-induced variations in interfacial chemistry should substantially affect our understanding and modeling of chemical processes at immersed surfaces. ",

author = "Dan Lis and {Backus H. G.}, Ellen and Johannes Hunger and {Parekh H.}, Sapun and Mischa Bonn",

year = "2014",

month = jun,

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doi = "10.1126/science.1253793",

language = "English",

volume = "344",

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journal = "Science",

issn = "1095-9203",

publisher = "American Association for the Advancement of Science",

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T1 - Liquid flow along a solid surface reversibly alters interfacial chemistry

AU - Lis, Dan

AU - Backus H. G., Ellen

AU - Hunger, Johannes

AU - Parekh H. , Sapun

AU - Bonn, Mischa

PY - 2014/6/6

Y1 - 2014/6/6

N2 - n nature, aqueous solutions often move collectively along solid surfaces (for example, raindrops falling on the ground and rivers flowing through riverbeds). However, the influence of such motion on water-surface interfacial chemistry is unclear. In this work, we combine surface-specific sum frequency generation spectroscopy and microfluidics to show that at immersed calcium fluoride and fused silica surfaces, flow leads to a reversible modification of the surface charge and subsequent realignment of the interfacial water molecules. Obtaining equivalent effects under static conditions requires a substantial change in bulk solution pH (up to 2 pH units), demonstrating the coupling between flow and chemistry. These marked flow-induced variations in interfacial chemistry should substantially affect our understanding and modeling of chemical processes at immersed surfaces.

AB - n nature, aqueous solutions often move collectively along solid surfaces (for example, raindrops falling on the ground and rivers flowing through riverbeds). However, the influence of such motion on water-surface interfacial chemistry is unclear. In this work, we combine surface-specific sum frequency generation spectroscopy and microfluidics to show that at immersed calcium fluoride and fused silica surfaces, flow leads to a reversible modification of the surface charge and subsequent realignment of the interfacial water molecules. Obtaining equivalent effects under static conditions requires a substantial change in bulk solution pH (up to 2 pH units), demonstrating the coupling between flow and chemistry. These marked flow-induced variations in interfacial chemistry should substantially affect our understanding and modeling of chemical processes at immersed surfaces.

U2 - 10.1126/science.1253793

DO - 10.1126/science.1253793

M3 - Article

SN - 1095-9203

VL - 344

SP - 1138

EP - 1142

JO - Science

JF - Science

IS - 6188

ER -

Liquid flow along a solid surface reversibly alters interfacial chemistry

Abstract

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