Accurate computation of quantum excited states with neural networks

Accurate computation of quantum excited states with neural networks

We present an algorithm to estimate the excited states of a quantum system by variational Monte Carlo, which has no free parameters and requires no orthogonalization of the states, instead transforming the problem into that of finding the ground state of an expanded system. Arbitrary observables can...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2024-08, Vol.385 (6711), p.eadn0137
Hauptverfasser: Pfau, David, Axelrod, Simon, Sutterud, Halvard, von Glehn, Ingrid, Spencer, James S
Format: Artikel
Sprache:eng
Schlagworte:
Accuracy
Adiabatic
Artificial neural networks
Atomic properties
Benchmarks
Benzene
Chemical bonds
Computation
Computer applications
Condensed matter physics
Couplings
Deep learning
Estimates
Excitation
First principles
Fluorescent indicators
Ground state
Hamiltonian functions
Hydrocarbons
Light emitting diodes
Machine learning
Mathematical analysis
Mathematical models
Mathematics
Molecular modelling
Networks
Neural networks
Nuclear physics
Organic Chemistry
Oscillator strengths
Photovoltaic cells
Physics
Potential energy
Prior Learning
Quantum chemistry
Quantum dots
Solar cells
Wave functions
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Beschreibung
Zusammenfassung:We present an algorithm to estimate the excited states of a quantum system by variational Monte Carlo, which has no free parameters and requires no orthogonalization of the states, instead transforming the problem into that of finding the ground state of an expanded system. Arbitrary observables can be calculated, including off-diagonal expectations, such as the transition dipole moment. The method works particularly well with neural network ansätze, and by combining this method with the FermiNet and Psiformer ansätze, we can accurately recover excitation energies and oscillator strengths on a range of molecules. We achieve accurate vertical excitation energies on benzene-scale molecules, including challenging double excitations. Beyond the examples presented in this work, we expect that this technique will be of interest for atomic, nuclear, and condensed matter physics.
ISSN:0036-8075
1095-9203
1095-9203
DOI:10.1126/science.adn0137