Calculation of Solvation Free-Energy Differences for Large Solute Change from Computer Simulations with Quadrature-Based Nearly Linear Thermodynamic Integration
- 1 August 1993
- journal article
- research article
- Published by Taylor & Francis in Molecular Simulation
- Vol. 10 (2-6) , 225-239
- https://doi.org/10.1080/08927029308022166
Abstract
The free-energy simulation methodology is reviewed from the point of view of calculating large free-energy differences. The advantages of the nearly linear thermodynamic integration based on Gaussian quadrature are highlighted and its performance is characterized on systems ranging from the Lennard-Jones fluid to the A to B transition of DNA oligomers. A technique for optimizing the runlength at each quadrature point is given. Examples for the sensitivity of the calculated free energy to the atomic charges used are also presented.Keywords
This publication has 50 references indexed in Scilit:
- Simple analysis of noise and hysteresis in (slow-growth) free energy simulationsThe Journal of Physical Chemistry, 1991
- Estimation of errors in free energy calculations due to the lag between the hamiltonian and the system configurationThe Journal of Physical Chemistry, 1991
- Evaluation of the Adaptive Umbrella Sampling MethodMolecular Simulation, 1989
- Direct Calculation of the Excess Free Energy of the Dense Lennard-Jones FluidMolecular Simulation, 1989
- Test of the overlap ratio method on the calculation of the aqueous hydration free energy difference between acetone and dimethylamineMolecular Physics, 1988
- Direct determination of phase coexistence properties of fluids by Monte Carlo simulation in a new ensembleMolecular Physics, 1987
- Grand-canonical ensemble Monte Carlo study of dense liquidMolecular Physics, 1987
- A Monte Carlo method for determining free-energy differences and transition state theory rate constantsThe Journal of Chemical Physics, 1985
- Comparison of simple potential functions for simulating liquid waterThe Journal of Chemical Physics, 1983
- Some Topics in the Theory of FluidsThe Journal of Chemical Physics, 1963