%0 Journal Article %1 Dressel2018 %A Dressel, Martin %A Zhukova, Elena S. %A Thomas, Victor G. %A Gorshunov, Boris P. %D 2018 %J Journal of Infrared, Millimeter, and Terahertz Waves %K dipole lattice %N 9 %P 799-815 %R 10.1007/s10762-018-0472-8 %T Quantum Electric Dipole Lattice: Water Molecules Confined to Nanocavities in Beryl %U https://doi.org/10.1007/s10762-018-0472-8 %V 39 %X Water is subject to intense investigations due to its importance in biological matter but keeps many of its secrets. Here, we unveil an even other aspect by confining H2O molecules to nanosize cages. Our THz and infrared spectra of water in the gemstone beryl evidence quantum tunneling of H2O molecules in the crystal lattice. The water molecules are spread out when confined in a nanocage. In combination with low-frequency dielectric measurements, we were also able to show that dipolar coupling among the H2O molecules leads towards a ferroelectric state at low temperatures. Upon cooling, a ferroelectric soft mode shifts through the THz range. Only quantum fluctuations prevent perfect macroscopic order to be fully achieved. Beside the significance to life science and possible application, nanoconfined water may become the prime example of a quantum electric dipolar lattice.

@article{Dressel2018, abstract = {Water is subject to intense investigations due to its importance in biological matter but keeps many of its secrets. Here, we unveil an even other aspect by confining H2O molecules to nanosize cages. Our THz and infrared spectra of water in the gemstone beryl evidence quantum tunneling of H2O molecules in the crystal lattice. The water molecules are spread out when confined in a nanocage. In combination with low-frequency dielectric measurements, we were also able to show that dipolar coupling among the H2O molecules leads towards a ferroelectric state at low temperatures. Upon cooling, a ferroelectric soft mode shifts through the THz range. Only quantum fluctuations prevent perfect macroscopic order to be fully achieved. Beside the significance to life science and possible application, nanoconfined water may become the prime example of a quantum electric dipolar lattice.}, added-at = {2019-06-28T14:21:09.000+0200}, author = {Dressel, Martin and Zhukova, Elena S. and Thomas, Victor G. and Gorshunov, Boris P.}, biburl = {https://puma.ub.uni-stuttgart.de/bibtex/263bc0e1da45c10272615ea4946ba6a6f/ulrikeoffenbeck}, day = 01, doi = {10.1007/s10762-018-0472-8}, interhash = {898b30b67140faaf46938cae64ea7356}, intrahash = {63bc0e1da45c10272615ea4946ba6a6f}, issn = {1866-6906}, journal = {Journal of Infrared, Millimeter, and Terahertz Waves}, keywords = {dipole lattice}, month = sep, number = 9, pages = {799-815}, timestamp = {2019-06-28T12:21:09.000+0200}, title = {Quantum Electric Dipole Lattice: Water Molecules Confined to Nanocavities in Beryl}, url = {https://doi.org/10.1007/s10762-018-0472-8}, volume = 39, year = 2018 }