Lixue Cheng, P. Bernát Szabó, Zeno Schätzle, Derk Kooi, Jonas Köhler, Klaas J. H. Giesbertz, Frank Noé, Jan Hermann, Paola Gori-Giorgi, Adam Foster
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Highly Accurate Real-space Electron Densities with Neural Networks
Variational ab-initio methods in quantum chemistry stand out among other
methods in providing direct access to the wave function. This allows in
principle straightforward extraction of any other observable of interest,
besides the energy, but in practice this extraction is often technically
difficult and computationally impractical. Here, we consider the electron
density as a central observable in quantum chemistry and introduce a novel
method to obtain accurate densities from real-space many-electron wave
functions by representing the density with a neural network that captures known
asymptotic properties and is trained from the wave function by score matching
and noise-contrastive estimation. We use variational quantum Monte Carlo with
deep-learning ans\"atze (deep QMC) to obtain highly accurate wave functions
free of basis set errors, and from them, using our novel method,
correspondingly accurate electron densities, which we demonstrate by
calculating dipole moments, nuclear forces, contact densities, and other
density-based properties.