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Data-Driven Collective Variables for Enhanced Sampling

Luigi Bonati, Valerio Rizzi, Michele Parrinello

2020The Journal of Physical Chemistry Letters227 citationsDOIOpen Access PDF

Abstract

Designing an appropriate set of collective variables is crucial to the success of several enhanced sampling methods. Here we focus on how to obtain such variables from information limited to the metastable states. We characterize these states by a large set of descriptors and employ neural networks to compress this information in a lower-dimensional space, using Fisher's linear discriminant as an objective function to maximize the discriminative power of the network. We test this method on alanine dipeptide, using the nonlinearly separable data set composed by atomic distances. We then study an intermolecular aldol reaction characterized by a concerted mechanism. The resulting variables are able to promote sampling by drawing nonlinear paths in the physical space connecting the fluctuations between metastable basins. Lastly, we interpret the behavior of the neural network by studying its relation to the physical variables. Through the identification of its most relevant features, we are able to gain chemical insight into the process.

Topics & Concepts

Discriminative modelLinear discriminant analysisArtificial neural networkSampling (signal processing)Computer scienceFocus (optics)Artificial intelligenceSet (abstract data type)Identification (biology)MathematicsStatistical physicsPhysicsFilter (signal processing)Computer visionOpticsProgramming languageBiologyBotanyMachine Learning in Materials ScienceProtein Structure and DynamicsSpectroscopy and Quantum Chemical Studies