Litcius/Paper detail

Non-bonded force field model with advanced restrained electrostatic potential charges (RESP2)

Michael Schauperl, Paul S. Nerenberg, Hyesu Jang, Lee‐Ping Wang, Christopher I. Bayly, David L. Mobley, Michael K. Gilson

2020Communications Chemistry304 citationsDOIOpen Access PDF

Abstract

The restrained electrostatic potential (RESP) approach is a highly regarded and widely used method of assigning partial charges to molecules for simulations. RESP uses a quantum-mechanical method that yields fortuitous overpolarization and thereby accounts only approximately for self-polarization of molecules in the condensed phase. Here we present RESP2, a next generation of this approach, where the polarity of the charges is tuned by a parameter, δ, which scales the contributions from gas- and aqueous-phase calculations. When the complete non-bonded force field model, including Lennard-Jones parameters, is optimized to liquid properties, improved accuracy is achieved, even with this reduced set of five Lennard-Jones types. We argue that RESP2 with δ≈0.6 (60% aqueous, 40% gas-phase charges) is an accurate and robust method of generating partial charges, and that a small set of Lennard-Jones types is good starting point for a systematic re-optimization of this important non-bonded term.

Topics & Concepts

Partial chargeElectrostaticsForce field (fiction)MoleculePolarization (electrochemistry)Charge (physics)Polarity (international relations)Statistical physicsAqueous solutionPoint (geometry)Point particleMaterials scienceChemistryChemical physicsPhysicsClassical mechanicsQuantum mechanicsPhysical chemistryMathematicsGeometryBiochemistryCellSpectroscopy and Quantum Chemical StudiesAdvanced Chemical Physics StudiesAdvanced Physical and Chemical Molecular Interactions