Abstract
We present NeuralIL, a model for the potential energy of an ionic liquid that accurately reproduces first-principles results with orders-of-magnitude savings in computational cost. Built on the basis of a multilayer perceptron and spherical Bessel descriptors of the atomic environments, NeuralIL is implemented in such a way as to be fully automatically differentiable. It can thus be trained on ab initio forces instead of just energies, to make the most out of the available data, and can efficiently predict arbitrary derivatives of the potential energy. Using ethylammonium nitrate as the test system, we obtain out-of-sample accuracies better than 2 meV atom–1 (<0.05 kcal mol–1) in the energies and 70 meV Å–1 in the forces. We show that encoding the element-specific density in the spherical Bessel descriptors is key to achieving this. Harnessing the information provided by the forces drastically reduces the amount of atomic configurations required to train a neural network force field based on atom-centered descriptors. We choose the Swish-1 activation function and discuss the role of this choice in keeping the neural network differentiable. Furthermore, the possibility of training on small data sets allows for an ensemble-learning approach to the detection of extrapolation. Finally, we find that a separate treatment of long-range interactions is not required to achieve a high-quality representation of the potential energy surface of these dense ionic systems.
Highlights
Room-temperature ionic liquids[1] (ILs) are ionized substances that exist in the liquid state at temperatures below 100 °C
In this paper we present NEURALIL, an NNFF for ionic liquids1 (ILs) based on atom-centered descriptors
NEURALIL achieves a high accuracy in the prediction of forces, as evidenced by an mean absolute error (MAE) of 0.0656 eV Å−1 over a validation set with a mean absolute deviation of 1.11 eV Å−1
Summary
Room-temperature ionic liquids[1] (ILs) are ionized substances that exist in the liquid state at temperatures below 100 °C. Two broad classes can be defined: protic ILs, which are formed by a proton transfer from an acid to a base, and aprotic ILs based on an organic molecular cation and an anion that can range from a single atom to another complex structure. ILs are very interesting from a fundamental point of view because of the many peculiar features of their dynamics, arising from the competition of electrostatic, steric, and dispersion interactions among ions, but their prominence in the scientific literature is undoubtedly mostly due to their potential for applications in industry.[2] ILs as a class have some desirable properties in this regard, the best known one being the negligible vapor pressure of aprotic ILs, which makes it possible to use them as “green solvents”[3] free from leaks to the environment. It is plausible that tailored ILs could be found for many applications, leading to the inclusion of ILs under the label of “designer solvents” as well
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