Hydrated Excess Protons Can Create Their Own Water Wires

Grotthuss shuttling of an excess proton charge defect through hydrogen bonded water networks has long been the focus of theoretical and experimental studies. In this work we show that there is a related process in which water molecules move (“shuttle”) through a hydrated excess proton charge defect...

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Veröffentlicht in:	The journal of physical chemistry. B 2015-07, Vol.119 (29), p.9212-9218
Hauptverfasser:	Peng, Yuxing, Swanson, Jessica M. J, Kang, Seung-gu, Zhou, Ruhong, Voth, Gregory A
Format:	Artikel
Sprache:	eng
Schlagworte:	cations Cations - chemistry crystal structure Gibbs free energy Graphite - chemistry hydrogen bonding Hydrophobic and Hydrophilic Interactions hydrophobicity molecular dynamics Molecular Dynamics Simulation Nanostructures - chemistry nanotubes potassium Protons Solvents - chemistry Water - chemistry
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container_end_page	9218
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container_title	The journal of physical chemistry. B
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creator	Peng, Yuxing Swanson, Jessica M. J Kang, Seung-gu Zhou, Ruhong Voth, Gregory A
description	Grotthuss shuttling of an excess proton charge defect through hydrogen bonded water networks has long been the focus of theoretical and experimental studies. In this work we show that there is a related process in which water molecules move (“shuttle”) through a hydrated excess proton charge defect in order to wet the path ahead for subsequent proton charge migration. This process is illustrated through reactive molecular dynamics simulations of proton transport through a hydrophobic nanotube, which penetrates through a hydrophobic region. Surprisingly, before the proton enters the nanotube, it starts “shooting” water molecules into the otherwise dry space via Grotthuss shuttling, effectively creating its own water wire where none existed before. As the proton enters the nanotube (by 2–3 Å), it completes the solvation process, transitioning the nanotube to the fully wet state. By contrast, other monatomic cations (e.g., K+) have just the opposite effect, by blocking the wetting process and making the nanotube even drier. As the dry nanotube gradually becomes wet when the proton charge defect enters it, the free energy barrier of proton permeation through the tube via Grotthuss shuttling drops significantly. This finding suggests that an important wetting mechanism may influence proton translocation in biological systems, i.e., one in which protons “create” their own water structures (water “wires”) in hydrophobic spaces (e.g., protein pores) before migrating through them. An existing water wire, e.g., one seen in an X-ray crystal structure or MD simulations without an explicit excess proton, is therefore not a requirement for protons to transport through hydrophobic spaces.
doi_str_mv	10.1021/jp5095118
format	Article
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subjects	cations Cations - chemistry crystal structure Gibbs free energy Graphite - chemistry hydrogen bonding Hydrophobic and Hydrophilic Interactions hydrophobicity molecular dynamics Molecular Dynamics Simulation Nanostructures - chemistry nanotubes potassium Protons Solvents - chemistry Water - chemistry
title	Hydrated Excess Protons Can Create Their Own Water Wires
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