Abstract
Translational diffusion coefficients are routinely estimated from molecular dynamics simulations. Linear fits to mean squared displacement (MSD) curves have become the de facto standard, from simple liquids to complex biomacromolecules. Nonlinearities in MSD curves at short times are handled with a wide variety of ad hoc practices, such as partial and piece-wise fitting of the data. Here, we present a rigorous framework to obtain reliable estimates of the self-diffusion coefficient and its statistical uncertainty. We also assess in a quantitative manner if the observed dynamics is, indeed, diffusive. By accounting for correlations between MSD values at different times, we reduce the statistical uncertainty of the estimator and, thereby, increase its efficiency. With a Kolmogorov-Smirnov test, we check for possible anomalous diffusion. We provide an easy-to-use Python data analysis script for the estimation of self-diffusion coefficients. As an illustration, we apply the formalism to molecular dynamics simulation data of pure TIP4P-D water and a single ubiquitin protein. In another paper [S. von Bülow, J. T. Bullerjahn, and G. Hummer, J. Chem. Phys. 153, 021101 (2020)], we demonstrate its ability to recognize deviations from regular diffusion caused by systematic errors in a common trajectory "unwrapping" scheme that is implemented in popular simulation and visualization software.
Highlights
Brownian motion is one of the pillars of biological physics, being observed on both microscopic and mesoscopic scales
We have solely focused on one-dimensional time series, while two- and three-dimensional particle trajectories are recorded in experiments and molecular dynamics (MD) simulations
We propose a robust framework to extract reliable selfdiffusion coefficients and their uncertainties from molecular dynamics simulation trajectories
Summary
Brownian motion is one of the pillars of biological physics, being observed on both microscopic and mesoscopic scales. Einstein’s seminal work established the mean squared displacement (MSD) as the central observable to characterize the jittering motion of microscopic objects. D is commonly estimated via linear fits to measured MSDs, which at first glance may seem like a rigorous approach, because the resulting estimate is unbiased. The precision of the estimate suffers if too many MSD values are used for the fit.. The precision of the estimate suffers if too many MSD values are used for the fit.3,4 This counter-intuitive behavior results from the fact that the most common estimator for the MSD of a finite time series {X0, X1, . The precision of the estimate suffers if too many MSD values are used for the fit. This counter-intuitive behavior results from the fact that the most common estimator for the MSD of a finite time series {X0, X1, . . ., XN −1, XN }, namely, MSDi
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