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Diffusion processes in water on oxide surfaces: Quasielastic neutron scattering study of hydration water in rutile nanopowder.
- Source :
-
Physical Review E: Statistical, Nonlinear & Soft Matter Physics . Sep2011, Vol. 84 Issue 3-1, p031505-1-031505-7. 7p. - Publication Year :
- 2011
-
Abstract
- Quasielastic neutron scattering (QENS) was used to investigate the diffusion dynamics of hydration water on the surface of futile (TiO2) nanopowder. The dynamics measurements utilizing two inelastic instruments, a backscattering spectrometer and a disk chopper spectrometer, probed the fast, intermediate, and slow motions of the water molecules on the time scale of picoseconds to more than a nanosecond. We employed a model-independent analysis of the data collected at each value of the scattering momentum transfer to investigate the temperature dependence of several diffusion components. All of the probed components were present in the studied temperature range of 230-320 K, providing, at a first sight, no evidence of discontinuity in the hydration water dynamics. However, a qualitative change in the elastic scattering between 240 and 250 K suggested a surface freezing-melting transition, when the motions that were localized at lower temperatures became delocalized at higher temperatures. On the basis of our previous molecular dynamics simulations of this system, we argue that interpretation of QENS data from such a complex interfacial system requires at least qualitative input from simulations, particularly when comparing results from spectrometers with very different energy resolutions and dynamic ranges. [ABSTRACT FROM AUTHOR]
- Subjects :
- *QUASIELASTIC neutron scattering
*DIFFUSION
*HYDRATION
*MOLECULAR dynamics
*WATER
Subjects
Details
- Language :
- English
- ISSN :
- 15393755
- Volume :
- 84
- Issue :
- 3-1
- Database :
- Academic Search Index
- Journal :
- Physical Review E: Statistical, Nonlinear & Soft Matter Physics
- Publication Type :
- Academic Journal
- Accession number :
- 70195012
- Full Text :
- https://doi.org/10.1103/PhysRevE.84.031505