Protonated water clusters, which have protons bound to them, are important model systems for the study of proton hydration in aqueous solutions, the process that determines the acidity (pH) and electrical conductivity of water.
The smallest protonated water cluster is the hydronium cation consisting of a single water molecule with an associated proton.
The Zundel ion is another protonated water cluster and is formed when a single proton is shared by two water molecules.
Scientists have been using infrared spectroscopy to determine the bond strengths, geometrical structures and chemical properties of protonated water clusters. When molecules are irradiated with infrared light, they vibrate in ways that depend on the wavelength, the colour, of the light. The frequency of the resulting vibrations allows scientists to deduce the three-dimensional structure of the molecule and the strength of the bonds between its atoms.
Reference:
- Marcel sBaer, Dominik Marx, Gerald Mathias. Theoretical Messenger Spectroscopy of Microsolvated Hydronium and Zundel Cations. Angewandte Chemie, 23 August 2010 DOI: 10.1002/anie.201001672
- G. Mathias, D. Marx. Structures and spectral signatures of protonated water networks in bacteriorhodopsin. Proceedings of the National Academy of Sciences, 2007; 104 (17): 6980 DOI: 10.1073/pnas.0609229104
Study Questions
- Draw the molecular structure of a water molecule.
- Use the structure above to explain what is meant by water being a polar molecule.
- Draw a diagram to show how a hydrogen-bond can be formed between two water molecules.
- Write the molecular formula for the hydronium cation.
- Give the structural formala for the hydronium ion.
- Based on the description of the Zundel ion given above, write the molecular formula for the Zundel ion.
- Give the structural formula for the Zundel ion.
- Another protonated water cluster is the Eigen ion, H9O4+ . Give a possible structural formula for the Eigen ion.
No comments:
Post a Comment