posted on 2019-04-17, 00:00authored byAndreas Singraber, Tobias Morawietz, Jörg Behler, Christoph Dellago
Over
the past years high-dimensional neural network potentials
(HDNNPs), fitted to accurately reproduce ab initio potential energy
surfaces, have become a powerful tool in chemistry, physics and materials
science. Here, we focus on the training of the neural networks that
lies at the heart of the HDNNP method. We present an efficient approach
for optimizing the weight parameters of the neural network via multistream
Kalman filtering, using potential energies and forces as reference
data. In this procedure, the choice of the free parameters of the
Kalman filter can have a significant impact on the fit quality. Carrying
out a large parameter study, we determine optimal settings and demonstrate
how to optimize training results of HDNNPs. Moreover, we illustrate
our HDNNP training approach by revisiting previously presented fits
for water and developing a new potential for copper sulfide. This
material, accessible in computer simulations so far only via first-principles
methods, forms a particularly complex solid structure at low temperatures
and undergoes a phase transition to a superionic state upon heating.
Analyzing MD simulations carried out with the Cu2S HDNNP,
we confirm that the underlying ab initio reference method indeed reproduces
this behavior.