Electronic Structure Beyond DFT
Understanding the electronic properties of complex materials from first principles represents a major challenge in quantum physics, driven by the large system sizes and the vast number of degrees of freedom—such as spin, orbital, and lattice—that characterize these systems.
While ab initio methods grounded in density functional theory (DFT) provide key microscopic insights into many materials, their effectiveness is constrained when strong electron correlations are involved. In such scenarios, quantum many-body methods become indispensable. However, direct application of these techniques to complex materials from first principles is often hindered by the overwhelming number of interacting degrees of freedom and competing energy scales.
At CCQ, we are pioneering the development and implementation of advanced computational frameworks that extend the reach of powerful many-body approaches to quantum materials, all from first principles. A central thrust of this work is the integration of ab initio GW methods with quantum embedding methods such as extended dynamical mean-field theory (EDMFT). The development of a new efficient implementation of the GW method is the focus of the COQUÍ code, and our implementation of fully self-consistent GW+EDMFT combines this code with the ModEST code, a redesigned interface between the TRIQS code and electronic structure methods. GW is also being combined with other many-body methods such as AFQMC. Additionally, fast embedding solvers based on the ghost-Gutzwiller approach are being developed and, when combined with DFT or GW, are poised to yield novel and efficient methodologies for the study of quantum materials. These efforts are closely aligned with CCQ’s broader initiatives in quantum embedding, quantum Monte Carlo, and tensor network methods .
Project Leader: Miguel Morales
Project Scientists: Jennifer Coulter, Antoine Georges, Olivier Gingras, Harrison LaBollita, Jaemo Lihm, Miguel Morales, Olivier Parcollet, Chia-Nan Yeh