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Classical molecular mechanics (MM) force fields rely on accurate atomic charges. This study shows density functional theory (DFT) methods provide more accurate charges than Hartree-Fock (HF) for MM force fields.

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Area of Science:

  • Computational Chemistry
  • Molecular Modeling
  • Physical Chemistry

Background:

  • Classical molecular mechanics (MM) force fields are crucial for condensed phase simulations.
  • Accurate modeling of nonbonded interactions, particularly electrostatics, is vital for MM force field accuracy.
  • Popular fixed-charge MM force fields often use partial atomic charges derived from gas-phase Hartree-Fock (HF)/6-31G* calculations.

Purpose of the Study:

  • To evaluate the accuracy of HF/6-31G* for deriving partial atomic charges for MM force fields.
  • To investigate alternative, computationally inexpensive methods for generating more accurate partial atomic charges.
  • To assess the suitability of density functional theory (DFT) methods for next-generation MM force field development.

Main Methods:

  • Evaluated HF/6-31G* method/basis set combination using a benchmark set of 47 molecules.
  • Compared calculated gas-phase dipole moments with experimental values.
  • Investigated computationally inexpensive DFT methods with augmented basis sets and a continuum solvent model.

Main Results:

  • HF/6-31G* overpolarizes molecular dipole moments by approximately 10% on average compared to experimental gas-phase values.
  • The degree of overpolarization with HF/6-31G* is inconsistent, sometimes resulting in lower dipole moments than experimental.
  • DFT methods with appropriate basis sets and solvent models yield more consistently and strongly overpolarized molecular dipole moments.

Conclusions:

  • The HF/6-31G* method/basis set is not optimal for deriving partial atomic charges for MM force fields due to inconsistent overpolarization.
  • Computationally inexpensive DFT methods offer a promising alternative for generating accurate partial atomic charges.
  • Adoption of DFT-based methods is recommended for developing next-generation MM force fields with improved accuracy.