TurboRVB Code: one of the TREX’s flagship codes
Watch the video interview of Professor Sandro Sorella and learn more about the TurboRVB code, one of TREX’s flagship codes.
TurboRVB is a package for ab initio QMC simulations of both molecular and bulk electronic systems. The code implements two types of well-established QMC algorithms: Variational Monte Carlo (VMC) and diffusion Monte Carlo in its robust and efficient lattice regularized variant. A key feature of the code is the possibility to use strongly correlated many-body wave functions, capable of describing several materials with very high accuracy, even when standard mean-field approaches such as density functional theory (DFT) fail.
The code implements the adjoint algorithmic differentiation that enables a very efficient evaluation of energy derivatives, comprising the ionic forces. Thus, one can perform structural optimizations and molecular dynamics in the canonical NVT ensemble at the VMC level. For the electronic part, a full WF optimization (Jastrow and antisymmetric parts together) is made possible thanks to state-of-the-art stochastic algorithms for energy minimization. In the optimization procedure, the first guess can be obtained at the mean-field level by a built-in DFT driver.
Interview with Sandro Sorella, recorded in Versailles in March 2022 during the TREX All-hands meeting
TurboRVB code, one of the flagship codes of the TREX project, was founded and developed by Sandro Sorella, a professor of the Condensed Matter Theory Sector at SISSA.
Sandro was the world master in the science and art of Quantum Monte Carlo computer simulation of interacting fermion systems. He made many groundbreaking contributions to many-body physics in several fields, both for the development of numerical methods for quantum systems and in using them to understand many-body physics. His simulations have led to an important understanding of lattice models describing strongly correlated systems such as Mott insulators, including prophetic work on their topological description, high-temperature superconductors and also realistic models of condensed matter systems such as hydrogen at high pressures and electronic correlation in molecules.
His focus was on the study of strongly-correlated electron systems by advanced numerical simulation techniques based on quantum Monte Carlo. He developed novel Monte Carlo algorithms that are now widely used and considered state-of-the-art in the field.
If you want to learn more about his contributions to the Quantum Monte Carlo and TurboRVB study, download the presentations given at the Psi-k 2022 conference during the memorial session dedicated to Sandro:
- Sandro’s legacy: 3 generations of scientists (Download) - Matteo Calandra, Department of Physics, University of Trento, Italy
- Sandro's contribution to ab initio calculations (Download) - Michele Casula, CNRS and Sorbonne University, Paris, France
- Memory of our daily research and the TurboRVB family of codes (Download) - Kosuke Nakano, SISSA, Condensed matter theory group, JSPS overseas fellow JAIST, School of Information Science, Assistant Professor
- Sandro Sorella: Two of his Gems (Download) - Giuseppe Carleo, Computational Quantum Science Lab Institute of Physics, EPFL - Lausanne - Switzerland