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Award Abstract #0107541
Molecular Solvation Phenomena in Nanoscale Superfluids
| NSF Org: |
CHE
Division of Chemistry
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| Initial Amendment Date: |
August 1, 2001 |
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| Latest Amendment Date: |
May 9, 2003 |
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| Award Number: |
0107541 |
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| Award Instrument: |
Continuing grant |
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| Program Manager: |
Raima M. Larter
CHE Division of Chemistry
MPS Directorate for Mathematical & Physical Sciences
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| Start Date: |
August 1, 2001 |
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| Expires: |
July 31, 2004 (Estimated) |
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| Awarded Amount to Date: |
$375000 |
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| Investigator(s): |
K. Birgitta Whaley whaley@berkeley.edu (Principal Investigator)
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| Sponsor: |
University of California-Berkeley
Sponsored Projects Office
BERKELEY, CA 94704 510/642-8109
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| NSF Program(s): |
QUANTUM CALCULATIONS
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| Field Application(s): |
0000099 Other Applications NEC
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| Program Reference Code(s): |
OTHR, 0000
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| Program Element Code(s): |
1954
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ABSTRACT
Birgitta Whaley of the University of California, Berkeley, is supported by the Theoretical and Computational Chemistry Program to carry out microscopic theoretical analysis of two classes of novel quantum solvation phenomena that have been revealed by recent spectroscopic experiments, which remain theoretically unexplained. The aim is to uncover the role played by the underlying quantum structure and dynamics in the spectroscopic observables. The first phenomenon to be explored concerns the effect of "wrapping" a molecule with the solvation layer of molecular para-hydrogen and then embedding this in a helium cluster at ultra-low temperatures. The extent of nanosuperfluidity possible in the hydrogen and solvation wrap will be analyzed, along with the relation between the quantum statistics of this and the molecular spectroscopic constants. Secondly, helium solvent-induced modifications of structure and excitations of embedded molecules and complexes will be addressed, focusing on intramolecular tunneling, structures of heterocomplexes, and on the nature of the local solvation environment and associated solvent excitations around planar organic molecules. This research involves application of large-scale quantum simulation methodology, algorithmic advances in some cases, and a combination of simulations with theoretical analysis using dynamical models.
Small liquid clusters of helium that are produced in molecular beam expansions are becoming an increasingly popular new medium in which atoms and molecules can be embedded and studied experimentally. The clusters act as novel environments in which to examine ultra-low temperature properties of molecules, chemical reactions, and the energies of solvation. The outcomes of this project are expected to lead to new insights into the fundamental understanding of chemical and physical behavior in cold quantum mechanical solvents.
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