The GW approximation represents the state-of-the-art ab-initio method for computing excited-state properties. Its execution requires control over a larger number of parameters, and therefore, its application in high-throughput studies is hindered by the complex and time-consuming convergence process across a multidimensional parameter space. To address these challenges, we develop a fully-automated open-source workflow for G0W0 calculations within the AiiDA framework and the projector augmented wave (PAW) method. The workflow is based on an efficient estimation of the errors in the quasi-particle (QP) energies due to basis-set truncation and ultra-soft PAW potentials norm violation, which allows a reduction in the dimensionality of the parameter space and avoids the need for multidimensional convergence searches. Protocol validation is conducted through a systematic comparison against established experimental and state-of-the-art GW data. To demonstrate the effectiveness of the approach, we construct a database of QP energies for a dataset of over 320 bulk structures.
Varrassi, L., Ellinger, F., Flage-Larsen, E., Wolloch, M., Kresse, G., Marzari, N., et al. (2025). Automated workflow for accurate high-throughput GW calculations using plane waves. NPJ COMPUTATIONAL MATERIALS, 11(1), 1-14 [10.1038/s41524-025-01833-w].
Automated workflow for accurate high-throughput GW calculations using plane waves
Varrassi L.Primo
Investigation
;Franchini C.
Ultimo
Supervision
2025
Abstract
The GW approximation represents the state-of-the-art ab-initio method for computing excited-state properties. Its execution requires control over a larger number of parameters, and therefore, its application in high-throughput studies is hindered by the complex and time-consuming convergence process across a multidimensional parameter space. To address these challenges, we develop a fully-automated open-source workflow for G0W0 calculations within the AiiDA framework and the projector augmented wave (PAW) method. The workflow is based on an efficient estimation of the errors in the quasi-particle (QP) energies due to basis-set truncation and ultra-soft PAW potentials norm violation, which allows a reduction in the dimensionality of the parameter space and avoids the need for multidimensional convergence searches. Protocol validation is conducted through a systematic comparison against established experimental and state-of-the-art GW data. To demonstrate the effectiveness of the approach, we construct a database of QP energies for a dataset of over 320 bulk structures.| File | Dimensione | Formato | |
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