Aug 26 2015
New research by scientists from the University of Southampton has found that water molecules react differently to electric fields, which could provide a new way to study spin isomers at the single-molecule level.
Supramolecular endofullerene H2O@C60 or 'Buckyball'. Credit: University of Southampton
Water molecules exist in two forms or ‘isomers’, ortho and para, that have different nuclear spin states. In ortho-water, the nuclear spins are parallel to one another, and in para water, the spins are antiparallel. The conversion of ortho water into para-water and vice-versa is relevant to a broad range of scientific fields from nuclear magnetic resonance (NMR) to astrophysics.
While it is possible to separate ortho- and para-water molecules it is difficult to study them in bulk water because rapid proton exchange and hindered molecular rotation obscure the direct observation of the two spin isomers.
To help observe this transformation in bulk water, the Southampton research team confined single water molecules in C60 carbon cages or ‘buckyballs’ to produce supramolecular endofullerene H2O@C60. The yield of this chemical synthesis was improved dramatically by the team, allowing them to study bulk quantities of this substance.
The carbon cages prevent water molecules from freezing and keep them separate, so that they continue to rotate freely at very low temperatures, making it possible to study the conversion.
Since water has an electric dipole moment (a measure of the separation of positive and negative electrical charges), the researchers measured the dielectric constant of H2O@C60 at cryogenic temperatures and found that it decreases as water converts from ortho to para, in line with quantum theory and previous NMR studies.
Dr Benno Meier, Senior Research Fellow in Chemistry and lead author, says: “The bulk dielectric constant of H2O@C60 depends on the spin isomer composition of the encapsulated water molecules. The observed time-dependent change in the bulk dielectric constant at 5K, as encapsulated water converts from the ortho to the para isomer, is due to a change in molecular polarizibility on spin conversion.”
“This work is a result of a long-standing and fruitful collaboration between Professors Malcolm Levitt and Richard Whitby, who have been studying the ortho to para conversion on a molecular level for several years.”
Source: http://www.southampton.ac.uk/