Predicting long-term trends in physical properties from short-term molecular dynamics simulations using long short-term memory.
Kota NodaYasushi ShibutaPublished in: Journal of physics. Condensed matter : an Institute of Physics journal (2024)
This study proposes a novel long short-term memory (LSTM)-based model for predicting future physical properties based on partial data of molecular dynamics (MD) simulation. It extracts latent vectors from atomic coordinates of MD simulations using graph convolutional network, utilizes LSTM to learn temporal trends in latent vectors and make one-step-ahead predictions of physical properties through fully connected layers. Validating with MD simulations of Ni solid-liquid systems, the model achieved accurate one-step-ahead prediction for time variation of the potential energy during solidification and melting processes using residual connections. Recursive use of predicted values enabled long-term prediction from just the first 20 snapshots of the MD simulation. The prediction has captured the feature of potential energy bending at low temperatures, which represents completion of solidification, despite that the MD data in short time do not have such a bending characteristic. Remarkably, for long-time prediction over 900 ps, the computation time was reduced to 1/700th of a full MD simulation of the same duration. This approach has shown the potential to significantly reduce computational cost for prediction of physical properties by efficiently utilizing the data of MD simulation.
Keyphrases
- human health
- molecular dynamics
- risk assessment
- density functional theory
- molecular dynamics simulations
- physical activity
- mental health
- neural network
- electronic health record
- big data
- virtual reality
- machine learning
- working memory
- mass spectrometry
- deep learning
- artificial intelligence
- current status
- convolutional neural network