posted on 2015-05-12, 00:00authored bySunhwan Jo, Christophe Chipot, Benoît Roux
The performance and accuracy of different
simulation schemes for
estimating the entropy inferred from free energy calculations are
tested. The results obtained from replica-exchange molecular dynamics
(REMD) simulations based on a simplified toy model are compared to
exact numerically derived ones to assess accuracy and convergence.
It is observed that the error in entropy estimation decreases by at
least an order of magnitude and the quantities of interest converge
much faster when the simulations are coupled via a temperature REMD
algorithm and the trajectories from different temperatures are combined.
Simulations with the infinite-swapping method and its variants show
some improvement over the traditional nearest-neighbor REMD algorithms,
but they are more computationally expensive. To test the methodologies
further, the free energy profile for the reversible association of
two methane molecules in explicit water was calculated and decomposed
into its entropic and enthalpic contributions. Finally, a strategy
based on umbrella sampling computations carried out via simultaneous
temperature and Hamiltonian REMD simulations is shown to yield the
most accurate entropy estimation. The entropy profile between the
two methane molecules displays the characteristic signature of a hydrophobic
interaction.