Liquid water molecules are inherently asymmetric: New insight into the bonds between water molecule
Icebergs float on liquid water, 4°C cold water sinks to the bottom: With its anomalies, water still poses a number of scientific puzzles. Researchers led by Johannes Hunger at the Max Planck Institute for Polymer Research have investigated the bonds between a water molecule and its neighbors in the liquid phase. They have discovered that the distances to neighboring molecules are not just randomly distributed: The two hydrogen atoms of a water molecule form a strong and a weak bond with neighboring molecules. This inherent molecular asymmetry means that superstructures such as rings or chains can form transiently – a key towards a comprehensive understanding of the structure of liquid water.
Icebergs float on water because the underlying liquid water has a higher density than the iceberg. Liquid water itself has its highest density at 4°C - one of the so-called anomalies of water, i.e. properties of liquids that are rarely observed for other liquids.
The origins of these anomalies have long been the subject of scientific research. Researchers at the Max Planck Institute for Polymer Research have now discovered another piece to the puzzle to explain the special behavior of water.
Many of the anomalous properties of water can be traced to the special interactions between the individual water molecules - the so-called hydrogen bonds. Each water molecule can donate two of these bonds – one from each hydrogen atom – and accept two of them from other, neighboring molecules. Unlike in ice, these bonds are broken and re-formed on average 1 trillion times per second in liquid water, so that the water molecules can be packed closer together and move very quickly. Due to the rapid movement of the water molecules in the liquid, one might assume that the strength of the individual bonds to its neighbors is purely random.
However, the team led by group leader Johannes Hunger has discovered that the hydrogen bond distances are not simply random, but that two bonds of a molecule have different strengths: If one bond is very strong - i.e. the first neighboring water molecule is very close - the second hydrogen bond is weak - i.e. the second neighboring water molecule is further away.
These alternating bond distances lead to structuring of the nominally disordered liquid: if you move from one water molecule to the next and to the one after that, there is always a strongly bonded neighboring molecule. As a result, structures such as rings or chains of water molecules can form in the liquid. The structure of liquid water is therefore not just a random arrangement of individual water molecules but follows certain rules.
To obtain these results, the scientists diluted water with a solvent so that they could examine isolated water molecules. They made individual atoms of the water molecules vibrate with the help of lasers and investigated how the vibrations influence each other. This allowed them to measure the strength of individual hydrogen bonds and the strength of the neighboring bond at the same time.
The study, which has now been published in the journal “Nature Communications”, contributes to a comprehensive understanding of the anomalies of water at a molecular level.
Wissenschaftlicher Ansprechpartner:
Dr. Johannes Hunger
hunger@mpip-mainz.mpg.de
Originalpublikation:
Lucas Gunkel, Amelie A. Ehrhard, Carola S. Krevert, Bogdan A. Marekha, Mischa Bonn, Maksim Grechko & Johannes Hunger: Dynamic anti-correlations of water hydrogen bonds
Nature Communications | (2024)
https://doi.org/10.1038/s41467-024-54804-y
Weitere Informationen:
https://www.mpip-mainz.mpg.de/pm2024-12