Wrapping up hydrophobic hydration

30 Jun 2020 | Source: Ruhr Universität, Bochum

Studied in detail, the embedding of hydrophobic molecules in water looks quite different than previously assumed

In water, hydrophobic molecules are surrounded by a two different water populations: the inner shell forms a two-dimensional network of water molecules. The next layer is formed by a second water population that is almost bulk like but forms slightly stronger hydrogen bonds to the bulk water. The assumption to date was that tetrahedral, “ice-like” water dominate in the innermost hydration shell of hydrophobic molecules. The opposite is the case. These new findings were published by the team headed by Professor Martina Havenith, Chair of Physical Chemistry II and Speaker of the Ruhr Explores Solvation Cluster of Excellence at Ruhr-Universität Bochum (RUB) in The Journal of Physical Chemistry Letters on 18 June 2020.

Insights by THz spectroscopy and simulations

In their study, the researchers investigated the hydrogen bond network around the hydrophobic solvated alcohol tert-butanol, as researchers use alcohols as a prototype models for hydrophobic molecules. The team combined results from terahertz (THz) spectroscopy and simulations.

In THz spectroscopy, researchers measure the absorption of THz radiation in a sample. The absorption spectrum provides a fingerprint of the water network.

A thin layer

In their study they obtained a detailed picture of the water layers surrounding the molecule. “We refer to the innermost layer as ‘HB-wrap’, where HB stands for water hydrogen bond,” explains Martina Havenith. The top layer is called ‘HB-hydration2bulk’ as it described the interface to the bulk water. Combined, both layers of the coating are sometimes no thicker than a single layer of water molecules. “Occasionally, a single water molecule may be part of both layers,” says Havenith.

Inner layer is longer stable

When the temperature is increased, the outer layer melts first, the HP-wrap layer remains longer intact. “The inner layer has also less freedom to form distinct configurations due to the hydrophobicity of the solute,” elaborates the researcher. “As individual water molecules must always turn away from the alcohol, they form a two-dimensional, loose network.” Water molecules in the outer layer have more freedom to move and therefore also more possibilities to connect with other water molecules; researchers refer to this phenomenon as greater entropy.

This type of interaction is relevant for the folding processes of proteins as well as biomolecular recognition between a drug and its target molecule. Understanding the role of water plays a crucial role in the process.

The study was funded by the German Research Foundation (DFG) as part of the Ruhr Explores Solvation Cluster of Excellence, funding code EXC 2033-390677874-Resolv, by the German-French Dynawin-Grant 14-CE35-0011-01 by Agence national de la recherche and DFG, and by Genci-France-Grant 072484 (Cines/Idris/TGCC). Martina Havenith is funded by an Advanced Grant des European Research Council, grant number 695437.


Valeria Conti Nibali, Simone Pezzotti, Federico Sebastiani, Daria Ruth Galimberti, Gerhard Schwaab, Matthias Heyden, Marie-Pierre Gaigeot, Martina Havenith: Wrapping up hydrophobic hydration: locality matters, in Physical Chemistry Letters, 2020, DOI: 10.1021/acs.jpclett.0c00846


Prof. Dr. Martina Havenith
Physical Chemistry II
Faculty of Chemistry and Biochemistry
Ruhr-Universität Bochum
Phone: +49 234 32 28249