Abstract
Vibrational properties of molecular crystals are constantly used as structural fingerprints, in order to identify both the chemical nature and the structural arrangement of molecules. The simulation of these properties is typically very costly, especially when dealing with response properties of materials to e.g. electric fields, which require a good description of the perturbed electronic density. In this work, we use Gaussian process regression (GPR) to predict the static polarizability and dielectric susceptibility of molecules and molecular crystals. We combine this framework with ab initio molecular dynamics to predict their anharmonic vibrational Raman spectra. We stress the importance of data representation, symmetry, and locality, by comparing the performance of different flavors of GPR. In particular, we show the advantages of using a recently developed symmetry-adapted version of GPR. As an examplary application, we choose Paracetamol as an isolated molecule and in different crystal forms. We obtain accurate vibrational Raman spectra in all cases with fewer than 1000 training points, and obtain improvements when using a GPR trained on the molecular monomer as a baseline for the crystal GPR models. Finally, we show that our methodology is transferable across polymorphic forms: we can train the model on data for one crystal structure, and still be able to accurately predict the spectrum for a second polymorph. This procedure provides an independent route to access electronic structure properties when performing force-evaluations on empirical force-fields or machine-learned potential energy surfaces.
Highlights
Machine-learning (ML) models are becoming increasingly popular in the field of atomistic simulations, providing a way to obtain data-driven physical insights [1,2,3] and reduce the cost of simulations [4, 5]
We show a machine-learned Raman spectrum averaged over 16 subselections of the training set of 900 configurations each, along with its standard deviation (STD), and compare it to the one calculated from fully ab initio data
We proposed Gaussian process regression (GPR) models to predict vibrational Raman spectra, based on learning polarizability and susceptibility tensors obtained from density-functional perturbation theory
Summary
Machine-learning (ML) models are becoming increasingly popular in the field of atomistic simulations, providing a way to obtain data-driven physical insights [1,2,3] and reduce the cost of simulations [4, 5]. When dealing with the response of a material to an applied field, the cost of a first-principles calculation is often larger than that of force evaluation This is an area where one can take advantage of supervised learning techniques in order to reduce the cost ab initio simulations that make use of such response properties. Some of the present authors have shown that anharmonic vibrational Raman spectra calculated through a time-correlation formalism can be a powerful tool to identify structural fingerprints in molecular crystals [22, 23] Within this formalism, it is necessary to calculate ab initio molecular dynamics trajectories and compute the response quantities for subsequent atomic configuration, employing, for instance, density-functional perturbation theory (DFPT) [22, 24,25,26,27]. While there are several empirical potentials available that can be used to simulate the dynamics of molecular crystals [28], empirical models of the polarizability tensors are rare and poorly transferable [29]
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