TY - JOUR
TI - A study of Ar-N2 supercritical mixtures using neutron scattering, molecular dynamics simulations and quantum mechanical scattering calculations
AU - Soper, A.K.
AU - Skarmoutsos, I.
AU - Kłos, J.
AU - Samios, J.
AU - Marinakis, S.
JO - Journal of Molecular Liquids
PY - 2019
VL - 290
TODO - null
SP - null
PB - Elsevier B.V.
SN - 0167-7322
TODO - 10.1016/j.molliq.2019.111168
TODO - Argon;  Calculations;  Mixtures;  Molecular physics;  Molecular structure;  Neutron scattering;  Nitrogen;  Numerical methods;  Potential energy;  Potential energy surfaces;  Quantum chemistry;  Temperature;  Van der Waals forces, Ab initio potential energy surface;  Intermolecular equilibrium distance;  Intermolecular structures;  Molecular dynamics simulations;  Neutron scattering experiments;  Single-molecule dynamics;  Supercritical;  Supercritical mixtures, Molecular dynamics
TODO - The microscopic structure of Ar-N2 supercritical mixtures was obtained using neutron scattering experiments at temperatures between 128.4 and 154.1 K, pressures between 48.7 and 97.8 bar and various mole fractions. Molecular Dynamics simulations (MD) were used to study the thermodynamics, microscopic structure and single molecule dynamics at the same conditions. The agreement between experimental and theoretical results on the intermolecular structure was very good. Furthermore, a new explicitly-correlated coupled cluster potential energy surface was obtained for the Ar-N2 van der Waals complex. The ab initio potential energy surface (PES) was found to be in agreement with the MD interaction potential. The global minimum of the ab initio PES De = 98.66 cm−1 was located at the T-shaped geometry and at the intermolecular equilibrium distance of Re = 7.00a0. The dissociation energy of the complex was determined to be D0 = 76.86 cm−1. Quantum mechanical (QM) calculations on the newly obtained PES were used to provide the bound levels of the complex. Finally, integral and differential QM cross sections in Ar + N2 collisions were calculated at collision energy corresponding to the average temperature of the experiments and at room temperature. © 2019 Elsevier B.V.
ER -