Abstract
The kinetics of a dynamical system comprising two metastable states is formulated in terms of a finite-time propagator in phase space (position and velocity) adapted to the underdamped Langevin equation. Dimensionality reduction to a subspace of collective variables yields familiar expressions for the propagator, committor, and steady-state flux. A quadratic expression for the steady-state flux between the two metastable states can serve as a robust variational principle to determine an optimal approximate committor expressed in terms of a set of collective variables. The theoretical formulation is exploited to clarify the foundation of the string method with swarms-of-trajectories, which relies on the mean drift of short trajectories to determine the optimal transition pathway. It is argued that the conditions for Markovity within a subspace of collective variables may not be satisfied with an arbitrary short time-step and that proper kinetic behaviors appear only when considering the effective propagator for longer lag times. The effective propagator with finite lag time is amenable to an eigenvalue-eigenvector spectral analysis, as elaborated previously in the context of position-based Markov models. The time-correlation functions calculated by swarms-of-trajectories along the string pathway constitutes a natural extension of these developments. The present formulation provides a powerful theoretical framework to characterize the optimal pathway between two metastable states of a system.
Highlights
A central problem in computational biophysics is the characterization of the long-time kinetic behavior of molecular systems
To reduce the complexity of the problem, Maragliano et al.[6] assumed that the committor probability depends predominantly on a subset of collective variables (CVs), z ≡ {z1, z2, ..., zN}. These considerations provide the background that led to the development of the string method with CVs on the potential of mean force (PMF) surface W(z).[6]
Following Maragliano et al.,[6] we introduce an approximation to the exact committor function in phase space u to achieve a dimensionality reduction to the subspace of the CVs z
Summary
A central problem in computational biophysics is the characterization of the long-time kinetic behavior of molecular systems. The expansion in a small displacement defines the forward committor for the effective dynamics within the subspace z, recovering the backward Smoluchowski equation previously introduced in eq 9.41,50 In the context of the swarms-oftrajectories, the optimized string can be determined by linking the states A and B such that the projection of the mean drifts perpendicular to the tangent of the curve vanishes The purpose of this analysis is to display the possible relationship of a formulation based on a dynamical propagator with lag time τ to the familiar form of the Smoluchowski diffusion equation. While these results on a simple model are encouraging, more work is needed to further develop the staging strategy into a fully practical and reliable method
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