The Structure and Transport of Water and Hydrated Ions Within Hydrophobic, Nanoscale Channels

The Structure and Transport of Water and Hydrated Ions Within Hydrophobic, Nanoscale Channels [electronic resource]

The purpose of this project includes an experimental and modeling investigation into water and hydrated ion structure and transport at nanomaterials interfaces. This is a topic relevant to understanding the function of many biological systems such as aquaporins that efficiently shuttle water and ion...

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Bibliographic Details
Online Access: Online Access
Corporate Author: Lawrence Livermore National Laboratory (Researcher)
Format: Government Document Electronic eBook
Language:English
Published: Washington, D.C : Oak Ridge, Tenn. : United States. Dept. of Energy ; distributed by the Office of Scientific and Technical Information, U.S. Dept. of Energy, 2009.
Subjects:
Carbon.
Nuclear Magnetic Resonance.
Cell Membranes.
Nanotubes.
Simulation.
Relaxation Time.
Transport.
Water.
Chemical Shift.
Absorption Spectroscopy.
Electronic Structure.
Filtration.
Protons.
Inorganic, Organic, Physical And Analytical Chemistry.
Description
Summary:The purpose of this project includes an experimental and modeling investigation into water and hydrated ion structure and transport at nanomaterials interfaces. This is a topic relevant to understanding the function of many biological systems such as aquaporins that efficiently shuttle water and ion channels that permit selective transport of specific ions across cell membranes. Carbon nanotubes (CNT) are model nanoscale, hydrophobic channels that can be functionalized, making them artificial analogs for these biological channels. This project investigates the microscopic properties of water such as water density distributions and dynamics within CNTs using Nuclear Magnetic Resonance (NMR) and the structure of hydrated ions at CNT interfaces via X-ray Absorption Spectroscopy (XAS). Another component of this work is molecular simulation, which can predict experimental measurables such as the proton relaxation times, chemical shifts, and can compute the electronic structure of CNTs. Some of the fundamental questions this work is addressing are: (1) what is the length scale below which nanoscale effects such as molecular ordering become important, (2) is there a relationship between molecular ordering and transport?, and (3) how do ions interact with CNT interfaces? These are questions of interest to the scientific community, but they also impact the future generation of sensors, filters, and other devices that operate on the nanometer length scale. To enable some of the proposed applications of CNTs as ion filtration media and electrolytic supercapacitors, a detailed knowledge of water and ion structure at CNT interfaces is critical.
Item Description:Published through the Information Bridge: DOE Scientific and Technical Information.
06/15/2009.
"llnl-tr-413937"
Holt, J K; Wu, Y; Mehta, A; Herberg, J L; Schwegler, E.
Physical Description:PDF-file: 9 pages; size: 0.6 Mbytes.

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