IR Spectra of Phosphate Ions in Aqueous Solution:  Predictions of a DFT/MM Approach Compared with Observations

Due to the progress of density functional theory (DFT) accurate computations of vibrational spectra of isolated molecules have become a standard task in computational chemistry. This is not yet the case for solution spectra. To contribute to the exploration of corresponding computational procedures, here we suggest a more efficient variant of the so-called instantaneous normal-mode analysis (INMA). This variant applies conventional molecular dynamics (MD) simulations, which are based on nonpolarizable molecular mechanics (MM) force fields, to the rapid generation of a large ensemble of different solvation shells for a solute molecule. Short hybrid simulations, in which the solute is treated by DFT and the aqueous solvent by MM, start from snapshots of the MM solute−solvent MD trajectory and yield a set of statistically independent hydration shells partially adjusted to the DFT/MM force field. Within INMA, these shells are kept fixed at their 300 K structures, line spectra are calculated from the DFT/MM Hessians of the solute, and its inhomogeneously broadened solution spectra are derived by second-order statistics. As our test application we have selected the phosphate ions HPO4 2- and H2PO4 - because sizable solvation effects are expected for the IR spectra of these strongly polarizable ions. The widths, intensities, and spectral positions of the calculated bands are compared with experimental IR spectra recorded by us for the purpose of checking the computational procedures. These comparisons provide insights into the merits and limitations of the available DFT/MM approach to the prediction of IR spectra in the condensed phase.