2022
DOI: 10.1021/acs.jctc.2c00324
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Free Energy Landscapes, Diffusion Coefficients, and Kinetic Rates from Transition Paths

Abstract: We address the problem of constructing accurate mathematical models of the dynamics of complex systems projected on a collective variable. To this aim we introduce a conceptually simple yet effective algorithm for estimating the parameters of Langevin and Fokker–Planck equations from a set of short, possibly out-of-equilibrium molecular dynamics trajectories, obtained for instance from transition path sampling or as relaxation from high free-energy configurations. The approach maximizes the model likelihood ba… Show more

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Cited by 9 publications
(16 citation statements)
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“…The phase-space information used for RC optimization is represented by MD trajectories spanning transitions between the reactant and product regions of configuration space. We adopt TPS as a source of input data for several reasons: ,, (i) ergodic trajectories (spontaneously spanning the transitions) are unfeasible in the presence of free-energy barriers ≫ k B T , while TPS has an affordable cost for many systems; (ii) TPS trajectories are free from biasing forces and, at statistical convergence, faithfully reproduce ergodic trajectories; (iii) recent numerical evidence indicate that ∼100 TPS-like MD trajectories projected on a suitable CV are sufficient to reconstruct accurate free-energies and rates by means of overdamped Langevin models …”
Section: Theoretical Methodsmentioning
confidence: 99%
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“…The phase-space information used for RC optimization is represented by MD trajectories spanning transitions between the reactant and product regions of configuration space. We adopt TPS as a source of input data for several reasons: ,, (i) ergodic trajectories (spontaneously spanning the transitions) are unfeasible in the presence of free-energy barriers ≫ k B T , while TPS has an affordable cost for many systems; (ii) TPS trajectories are free from biasing forces and, at statistical convergence, faithfully reproduce ergodic trajectories; (iii) recent numerical evidence indicate that ∼100 TPS-like MD trajectories projected on a suitable CV are sufficient to reconstruct accurate free-energies and rates by means of overdamped Langevin models …”
Section: Theoretical Methodsmentioning
confidence: 99%
“…A newly proposed RC is accepted or rejected based on a Metropolis criterion aimed at minimizing the kinetic rate estimated from a maximum-likelihood Langevin model. The latter is optimized following the method in ref . For a sufficiently small time interval τ, the transition probability density p (propagator) between points q and q′ in the CV-space can be approximated as p ( q , t + τ | q , t ) 1 2 π μ e false( q q ϕ false) 2 / 2 μ ϕ = a τ + 1 2 ( a a + D a ) τ 2 , goodbreak0em1em⁣ μ = 2 D τ + ( a D + 2 a D + D D ) τ 2 where the prime indicates d / dq , a = − βDF′ + D′ is the drift in eq , and the approximation includes terms up to order τ 2 .…”
Section: Theoretical Methodsmentioning
confidence: 99%
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“…( 3) to obtain free energies. Kinetics: Given that the free energy profile as a function of the reaction coordinate λ is available, one simple approach to estimating the kinetics of spontaneous processes is to consider a diffusion process on this onedimensional energy landscape [27]. To estimate the timescales of slow processes in such a description, we take two different approaches.…”
Section: Theorymentioning
confidence: 99%
“…The resulting projection will suffer from local conformational landscapes of different local environments from other projected coordinates . Consequently, the local scape time that is represented by diffusion is commonly position-dependent ( D ( Q )). Folding and transition path times can take D ( Q ) into account in the Kramers’ original theory to deliver the underlying kinetics with improved accuracy. In addition, the coordinate-dependent drift-velocity coefficient ( v ( Q )), which is proportional to the gradient of the effective diffusive potential of the system, can be used to recover the one-dimensional free energy landscape ( F ( Q )). , An outcome of the diffusion theory is that D ( Q ) incorporates the multiple diffusions over local energetic barriers or microstates of F ( Q ). If present, the local kinetic traps might be uncovered by the position-dependent D and v .…”
Section: Introductionmentioning
confidence: 99%