Abstract
A water molecule encapsulated inside a C60 fullerene cage behaves almost like an asymmetric top rotor, as would be expected of an isolated water molecule. However, inelastic neutron scattering (INS) experiments show evidence of interactions between the water molecule and its environment [Goh et al., Phys. Chem. Chem. Phys., 2014, 16, 21330]. In particular, a resolved splitting of the 101 rotational level into a singlet and a doublet indicates that the water molecule experiences an environment of lower symmetry than the icosahedral symmetry of a C60 cage. Recent calculations have shown that the splitting can be explained in terms of electrostatic quadrupolar interactions between the water molecule and the electron clouds of nearest-neighbour C60 molecules, which results in an effective environment of S6 symmetry [Felker et al., Phys. Chem. Chem. Phys., 2017, 19, 31274 and Bačić et al., Faraday Discussions, 2018, 212, 547-567]. We use symmetry arguments to obtain a simple algebraic expression, expressed in terms of a linear combination of products of translational and rotational basis functions, that describes the effect on a water molecule of any potential of S6 symmetry. We show that we can reproduce the results of the electrostatic interaction model up to ≈12 meV in terms of two unknown parameters only. The resulting potential is in a form that can readily be used in future calculations, without needing to use density functional theory (DFT) for example. Adjusting parameters in our potential would help identify whether other symmetry-lowering interactions are also present if experimental results that resolve splittings in higher-energy rotational levels are obtained in the future. As another application of our model, we show that the results of DFT calculations of the variation in energy as a water molecule moves inside the cage of an isolated C60 molecule, where the water molecule experiences an environment of icosahedral symmetry, can also be reproduced using our model.
Highlights
Resulting from the interplay between van der Waals and hydrogen-bonding interactions 4 still have measurable effects on the properties of the water molecule
1 The relatively large inner cavity of C60 together with the absence of strong interactions between the water molecule and the C60 molecule provides a highly symmetric, nano-size laboratory in which the single-molecule behaviour of the encapsulated water molecule can be explored. 13C NMR and and ultraviolet-visible (UV-Vis) spectroscopy indicate that an encapsulated water molecule will rotate rapidly, at least on the timescale of NMR. 1 Nuclear spin conversion in NMR shows that the rotation is almost free, 2 as do Molecular Dynamics (MD) simulations
We have developed a potential that can be used to model the interactions between a water molecule encapsulated in a C60 cage and its environment
Summary
Resulting from the interplay between van der Waals (vdW) and hydrogen-bonding interactions 4 still have measurable effects on the properties of the water molecule. 16 We will discuss how our results compare to those of the electrostatic interaction model for a certain choice of parameters, and how choosing different parameters will account for the presence of additional interactions This will be important if experimental results that resolve splittings in higher excited states become available in the future. As a further example of how our model can be applied, we will construct an equivalent potential of icosahedral (Ih) symmetry, and show that it can be used to reproduce the results of DFT calculations showing the variation in energy of a water molecule as it moves along certain radial directions inside the cage of an isolated C60 molecule. We will compare results using our potential with both the results of the electrostatic interaction model and the results of our DFT calculations
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