Quantum Chemistry
Quantum chemistry aims to computationally predict molecular properties using quantum mechanics, traditionally relying on computationally expensive methods like Density Functional Theory (DFT) and Coupled Cluster. Current research heavily utilizes machine learning, employing graph neural networks, transformers, and restricted Boltzmann machines to create faster and more accurate predictive models, often trained on large datasets of molecular geometries and properties calculated at various levels of theory (multifidelity methods). These advancements significantly accelerate simulations, enabling studies of larger and more complex molecules, with applications ranging from drug discovery to materials science.
Papers
$\nabla^2$DFT: A Universal Quantum Chemistry Dataset of Drug-Like Molecules and a Benchmark for Neural Network Potentials
Kuzma Khrabrov, Anton Ber, Artem Tsypin, Konstantin Ushenin, Egor Rumiantsev, Alexander Telepov, Dmitry Protasov, Ilya Shenbin, Anton Alekseev, Mikhail Shirokikh, Sergey Nikolenko, Elena Tutubalina, Artur Kadurin
QeMFi: A Multifidelity Dataset of Quantum Chemical Properties of Diverse Molecules
Vivin Vinod, Peter Zaspel