Abstract
A polarizable potential function describing the interaction between acetonitrile
molecules is introduced. The molecules are described as rigid and linear with three
mass sites corresponding to the CH3 group (methyl, Me), the central carbon atom (C),
and the nitrogen atom (N). The electrostatic interaction is represented using a single
center multipole expansion (SCME) as has been done previously for H2O [Wikfeldt et
al., Phys. Chem. Chem. Phys. 15, 16542 (2013)], by including multipole moments
from dipole up to and including hexadecapole, as well as anisotropic dipole-dipole, dipole-quadrupole and quadrupole-quadrupole polarizability tensors. The model is free of point charges. The non-electrostatic part is described in a pair-wise fashion by a Born-Mayer repulsion and damped dispersion attraction. The potential function is parameterized to fit the interaction energy of small (CH3CN)n, n=2-6, clusters calculated using the PBE0 hybrid functional with an additional many-body dispersion contribution. The parameterized potential function is found to compare well with results of the electronic structure calculations of dissociation curves for different dimer orientations and cohesive properties (the equilibrium volume, cohesive energy, and the bulk modulus) of the α-phase of acetonitrile crystal. The average value of the molecular dipole moment obtained in the α-phase is 5.53 D, corresponding to a ca. 40% increase as compared to the dipole moment of an isolated acetonitrile molecule, 3.92
D.