Add to ORKGWe present a method for the efficient calculation of the electronic structure of semiconductors within the GW approach. It approximately includes dynamical-screening and local-field effects, previously disregarded in simplified GW approaches, without increasing the computational effort. Such effects substantially affect the gap corrections. We find quasiparticle shifts in good agreement with the complete GW calculations or experiment for Si, AlAs, GaAs and ZnSe
We present a quantitative parameter-free method for calculating defect states and charge-transition ...
In this thesis we describe the extension and implementation of the Sternheimer- GW method to a first...
We present a quantitative parameter-free method for calculating defect states and charge-transition ...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
Quasiparticle energies and band gaps in semiconductors determined with an efficient DFT-GW schem
Quasiparticle energies and band gaps in semiconductors determined with an efficient DFT-GW schem
We have applied the Green function theory in GW approximation to calculate the quasiparticle energie...
We successfully applied the Green function theory in GW approximation to calculate the quasiparticle...
We have applied the Green-function method in the GW approximation to calculate quasiparticle energie...
In this thesis we describe the extension and implementation of the Sternheimer- GW method to a first...
We present parameter-free calculations of the quasiparticle band structure of systems described by h...
We present a quantitative parameter-free method for calculating defect states and charge-transition ...
In this thesis we describe the extension and implementation of the Sternheimer- GW method to a first...
We present a quantitative parameter-free method for calculating defect states and charge-transition ...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
We present a method for the efficient calculation of the electronic structure of semiconductors with...
Quasiparticle energies and band gaps in semiconductors determined with an efficient DFT-GW schem
Quasiparticle energies and band gaps in semiconductors determined with an efficient DFT-GW schem
We have applied the Green function theory in GW approximation to calculate the quasiparticle energie...
We successfully applied the Green function theory in GW approximation to calculate the quasiparticle...
We have applied the Green-function method in the GW approximation to calculate quasiparticle energie...
In this thesis we describe the extension and implementation of the Sternheimer- GW method to a first...
We present parameter-free calculations of the quasiparticle band structure of systems described by h...
We present a quantitative parameter-free method for calculating defect states and charge-transition ...
In this thesis we describe the extension and implementation of the Sternheimer- GW method to a first...
We present a quantitative parameter-free method for calculating defect states and charge-transition ...