We present a detailed account of the GW space-time method. The method increases the size of systems whose electronic structure can be studied with a computational implementation of Hedin's GW approximation. At the heart of the method is a representation of the Green function G and the screened Coulomb interaction W in the real-space and imaginary-time domain, which allows a more efficient computation of the self-energy approximation Sigma = iGW. For intermediate steps we freely change between representations in real and reciprocal space on the one hand, and imaginary time and imaginary energy on the other, using fast Fourier transforms. The power of the method is demonstrated using the example of Si with artificially increased unit cell siz...
We solve the Dyson equation for atoms and diatomic molecules within the GW approximation, in order t...
The GW approximation to the electronic self-energy yields band structures in excellent agreement wit...
We propose a new method for calculating total energies of systems of interacting electrons, which re...
We describe the following new features which significantly enhance the power of the recently develop...
With the aim of identifying universal trends, we compare fully self-consistent electronic spectra an...
We present a new method for the computation of self-energy corrections in large supercells. It elimi...
We implement the GWspace-time method at finite temperatures, in which the Green's function G and the...
We investigate the performance of the GW approximation by comparison to exact results for small mode...
We present parameter-free calculations of the quasiparticle band structure of systems described by h...
GW calculations with a fully self-consistent Green’s function G and screened interaction W—based on ...
Excited-state calculations, notably for quasiparticle band structures, are nowadays routinely perfor...
We present a method to calculate the electronic charge density of periodic solids in the GW approxim...
International audienceThe GW approximation to the formally exact many-body perturbation theory has b...
The family of Green's function methods based on the $GW$ approximation has gained popularity in the ...
We implement the GW space-Time method at finite temperatures, in which the Green's function G and th...
We solve the Dyson equation for atoms and diatomic molecules within the GW approximation, in order t...
The GW approximation to the electronic self-energy yields band structures in excellent agreement wit...
We propose a new method for calculating total energies of systems of interacting electrons, which re...
We describe the following new features which significantly enhance the power of the recently develop...
With the aim of identifying universal trends, we compare fully self-consistent electronic spectra an...
We present a new method for the computation of self-energy corrections in large supercells. It elimi...
We implement the GWspace-time method at finite temperatures, in which the Green's function G and the...
We investigate the performance of the GW approximation by comparison to exact results for small mode...
We present parameter-free calculations of the quasiparticle band structure of systems described by h...
GW calculations with a fully self-consistent Green’s function G and screened interaction W—based on ...
Excited-state calculations, notably for quasiparticle band structures, are nowadays routinely perfor...
We present a method to calculate the electronic charge density of periodic solids in the GW approxim...
International audienceThe GW approximation to the formally exact many-body perturbation theory has b...
The family of Green's function methods based on the $GW$ approximation has gained popularity in the ...
We implement the GW space-Time method at finite temperatures, in which the Green's function G and th...
We solve the Dyson equation for atoms and diatomic molecules within the GW approximation, in order t...
The GW approximation to the electronic self-energy yields band structures in excellent agreement wit...
We propose a new method for calculating total energies of systems of interacting electrons, which re...