Water Clusters: Overview

Water clustering
Cluster and hydrogen-bond lifetimes are independent
Icosahedral water clusters

Plato thought that water could be represented by an icosahedron.
So do I. Read on and decide if we may be correct.

Water clustering

It is clear that life on Earth depends on the unusual structure and anomalous nature of liquid water. Organisms consist mostly of liquid water. This water performs many functions and it can never be considered simply as an inert diluent; it transports, lubricates, reacts, stabilizes, signals, structures and partitions. The living world should be thought of as an equal partnership between the biological molecules and water.

In spite of much work, many of the properties of water are puzzling. Enlightenment comes from an understanding that water molecules form an infinite hydrogen-bonded network with localized and structured clustering. The middling strength of the connecting hydrogen bonds seems ideally suited to life processes, being easily formed but not too difficult to break. An important concept, often overlooked, is that liquid water is not homogeneous at the nanoscopic level (e.g. see [993 ]).

Two water tetramer clusters forming an octamer cluster

Small clusters of four water molecules may come together to form water bicyclo-octamers. The molecular arrangement (A) also occurs in high-density ice-seven whereas, with 60° relative twist, (B) is found in low density hexagonal ice; (see animated gif, 129 kB). Such equilibria are balanced due to the existence of two minima in the potential energy (U) - molecular separation (r) diagram below, which shows the approach of the water tetramers.

This competition between Potential energy diagram of the approach of water tetramers showing a shallow minimum inside a deeper minimum maximizing van-der Waals interactions (A, yielding higher orientation entropy, higher density and individually weaker but more numerous water-water binding energies) and maximizing hydrogen bonding (B, yielding more ordered structuring, lower density and fewer but stronger water-water binding energies) is finely balanced, easily shifted with changed physical conditions, solutes and surfaces. The potential energy barrier between these states (see below left) ensures that water molecules prefer either structure A or B with little time spent on intermediate structures. An individual water molecule may be in state A with respect to some neighbors whilst being in state B with respect to others (for example, ice-seven).

The shallow minimum (a), due to non-bonded interactions, lies up to 20% inside the deeper minimum (b) due to hydrogen bonding (even allowing for a 15% closer approach of individual hydrogen bonded water molecules). In spatial terms, minimum (a) is far more extensive as the hydrogen-bonded minimum (b) is restricted in its geometry, being highly directional. At lower temperatures (particularly below the temperature of maximum density) and pressures, the less dense structure with more extensive hydrogen bonding at the lower minimum (b) will be preferred even though it involves a more ordered (lower entropy) structure. At higher temperatures, non-bonded interactions dominate causing breakdown of the clustering (Figure inspired by [16 ]).

The hydrogen bonding, although cohesive in nature, is thus holding the water molecules apart. It is the conflict between these two effects, and how it varies with conditions, which endows water with many of its unusual properties.

These bicyclo-octamers may cluster further, with only themselves, to form highly symmetric 280-molecule icosahedral water clusters that are able to interlink and tessellate throughout space. A mixture of water cyclic pentamers and tricyclo-decamers can bring about the same resultant clustering.

Cyclic pentamer Bicyclo-octamer Tricyclo-decamer

As all three of these small clusters are relatively stable, it is likely that their interaction will produce these larger icosahedral clusters. Such clusters can dynamically form a continuous network of both open, low-density, and condensed structures. [Back to Top ]

Shows how cluster lifetime is independent of hydrogen bond lifetime

Cluster and hydrogen-bond lifetimes are independent

Cartoon to aid the understanding of how the lifetimes of clusters are independent of the lifetime of individual linkages. The cartoon shows a two-dimensional representation of a three-dimensional phenomenon. The actual clusters of water molecules are not represented. It is supposed (opposite) that the star clusters (shown yellow filled) may reform around key structures (shown as rhombuses, sometimes red, but closed ring oligomers of H₂O in water). For each shifting cluster a few units move to break up the existing cluster and help create a new cluster. The new clusters are identical to the old ones but only contain a proportion of the units. Clusters may reform around any of the star arms. [Back to Top ]

Icosahedral water clusters

Cluster equilibrium, showing how the expanded low density icosahedral cluster (H2O)280 undergoes a partial collapse to give a more condensed structure

Such a fluctuating self-replicating network of water molecules, with localized and overlapping icosahedral symmetry, was first proposed to exist in liquid water in 1998 [55] and the structure subsequently independently found, by X-ray diffraction, in water nanodrops in 2001 [417 ]. The clusters formed can interconvert between lower and higher density forms by bending, but not breaking, some of the hydrogen bonds. Structuring may also flicker between statistically and topographically equivalent clusters but involving different molecules by shifting their cluster centers. As the temperature increases the average cluster size, the cluster integrity and the proportion in the low-density form all decrease. This structuring accommodates explanation of many of the anomalous properties of water including its temperature-density and pressure-viscosity behavior, the radial distribution pattern, the presence of both cyclic pentamers and hexamers, the change in properties on supercooling^a and the solvation and hydration properties of ions, hydrophobic molecules, carbohydrates and macromolecules. The model described here offers a "two-state" structural model on to which large molecules can be mapped in order to offer insights into their interactions. [Back to Top ]

Footnotes

^a As the temperature of supercooled water drops further below 0°C, the density, self-diffusion, thermal conductivity, enthalpy and entropy all decrease whereas compressibility, viscosity, thermal convection, specific heat (C_P) and gas solubility all increase. As the pressure increases on supercooled water, viscosity and freezing point decrease whereas entropy and self-diffusion increases. [Back]

Introduction to water clustering
The icosahedral water cluster, (H₂O)₂₈₀
Evidence for the icosahedral cluster model
Conclusions concerning water clustering