Density Functional Theory Based Studies on the Nature of Raman and Resonance Raman Scattering of Nerve Agent Bound to Gold and Oxide-Supported Gold Clusters: A Plausible Way of Detection

A detailed theoretical investigation has been carried out at the density functional level of theories to investigate the nature of Raman intensities of the -P═O stretching mode of a model nerve agent DFP (diisopropylfluorophosphate) when bound to different gold (Au8, Au20) and oxide-supported gold (MgO···Au4, CaO···Au4, TiO2···Au4, Al2O3···Au4, M16O16···Au8, and [M16O15···Au8]2+, M = Ca, Mg) clusters. All of these clusters and the DFP-bound clusters are fully optimized, and the computed energetics shows that DFP attaches itself weakly to these clusters. The normal Raman spectra calculations on these clusters show that there is substantial enhancement of the -P═O stretching mode of DFP compared to the isolated species. This enhancement has been found to be due to the polarization of the -P═O bond of DFP when bound to the clusters. Significant enhancement in intensity has been observed in the case of Aun···DFP (n = 8, 20), M16O16···Au8···DFP, and [M16O15···Au8]2+···DFP (M = Ca, Mg) clusters. The resonance Raman calculations on the Aun···DFP (n = 8, 20) reveals that this enhancement could be made quite large and selective, which is a feature that is unique to the nerve agents and could be used as a property for detecting them.