Formation and manipulation of confined water wires

Yongjae Lee; C. Dave Martin; John B. Parise; Joseph A. Hriljac; Thomas Vogt

doi:10.1021/nl049946n

Formation and manipulation of confined water wires

Yongjae Lee, C. Dave Martin, John B. Parise, Joseph A. Hriljac, Thomas Vogt

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

24 Citations (Scopus)

Abstract

Pressure-induced hydration (PIH) in the zeolite natrolite leads to well-ordered one-dimensional "water wires" and "water tubes". These structures provide urgently needed points of reference for molecular dynamics simulations and serve as models of transient and disordered biological nanowater. We show here that applying simultaneous pressure and temperature using a hydrothermal diamond anvil cell permits the intermolecular manipulation of water wires due to changes in the geometry of the host scaffolding and the enclosed hydrogen bonded water. During this process the ordered water wires formed under pressure change their direction depending on the temperature. This provides the opportunity to study the dynamics of confined water at the nanoscale by temperature and/or pressure-jump experiments. Our studies indicate that confined water responds differently to pressure and temperature than does bulk water.

Original language	English
Pages (from-to)	619-621
Number of pages	3
Journal	Nano letters
Volume	4
Issue number	4
DOIs	https://doi.org/10.1021/nl049946n
Publication status	Published - 2004 Apr

All Science Journal Classification (ASJC) codes

Bioengineering
Chemistry(all)
Materials Science(all)
Condensed Matter Physics
Mechanical Engineering

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10.1021/nl049946n

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abstract = "Pressure-induced hydration (PIH) in the zeolite natrolite leads to well-ordered one-dimensional {"}water wires{"} and {"}water tubes{"}. These structures provide urgently needed points of reference for molecular dynamics simulations and serve as models of transient and disordered biological nanowater. We show here that applying simultaneous pressure and temperature using a hydrothermal diamond anvil cell permits the intermolecular manipulation of water wires due to changes in the geometry of the host scaffolding and the enclosed hydrogen bonded water. During this process the ordered water wires formed under pressure change their direction depending on the temperature. This provides the opportunity to study the dynamics of confined water at the nanoscale by temperature and/or pressure-jump experiments. Our studies indicate that confined water responds differently to pressure and temperature than does bulk water.",

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T1 - Formation and manipulation of confined water wires

AU - Lee, Yongjae

AU - Martin, C. Dave

AU - Parise, John B.

AU - Hriljac, Joseph A.

AU - Vogt, Thomas

PY - 2004/4

Y1 - 2004/4

N2 - Pressure-induced hydration (PIH) in the zeolite natrolite leads to well-ordered one-dimensional "water wires" and "water tubes". These structures provide urgently needed points of reference for molecular dynamics simulations and serve as models of transient and disordered biological nanowater. We show here that applying simultaneous pressure and temperature using a hydrothermal diamond anvil cell permits the intermolecular manipulation of water wires due to changes in the geometry of the host scaffolding and the enclosed hydrogen bonded water. During this process the ordered water wires formed under pressure change their direction depending on the temperature. This provides the opportunity to study the dynamics of confined water at the nanoscale by temperature and/or pressure-jump experiments. Our studies indicate that confined water responds differently to pressure and temperature than does bulk water.

AB - Pressure-induced hydration (PIH) in the zeolite natrolite leads to well-ordered one-dimensional "water wires" and "water tubes". These structures provide urgently needed points of reference for molecular dynamics simulations and serve as models of transient and disordered biological nanowater. We show here that applying simultaneous pressure and temperature using a hydrothermal diamond anvil cell permits the intermolecular manipulation of water wires due to changes in the geometry of the host scaffolding and the enclosed hydrogen bonded water. During this process the ordered water wires formed under pressure change their direction depending on the temperature. This provides the opportunity to study the dynamics of confined water at the nanoscale by temperature and/or pressure-jump experiments. Our studies indicate that confined water responds differently to pressure and temperature than does bulk water.

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Formation and manipulation of confined water wires

Abstract

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