A many-body theory based on nonequilibrium Green functions, in which transport and optics are treated on a microscopic quantum-mechanical basis, is used to compute gain and absorption in the optical and terahertz regimes in quantum cascade laser structures. The relative importance of Coulomb interactions for different intersubband transitions depends strongly on the spatial overlap of the wave functions and the specific nonequilibrium populations within the subbands. The magnitude of the Coulomb effects can be controlled by changing the operation bias
Quantum cascade lasers can be modeled within a hierarchy of different approaches: Standard rate equa...
The theory of nonequilibrium Green functions allows for a quantitative modeling of quantum cascade l...
In this paper we present further details of a predictive Keldysh nonequilibrium many body Green's fu...
A many-body theory based on nonequilibrium Green functions, in which transport and optics are treate...
In this review we summarize current challenges for THz quantum cascade laser development as well as ...
The effects of many-body coulomb interaction and non-parabolicity on optical gain of terahertz quant...
The effects of many-body coulomb interaction and non-parabolicity on optical gain of terahertz quant...
Nonequilibrium optical gain is computed for quantum cascade lasers. The Greens functions theory cons...
A many-body theory is used to compute optical absorption due to intersubband transitions in structur...
The optical spectra of a quantum cascade laser structure under nonequilibrium conditions is studied ...
In this paper we apply a microscopic nonequilibrium many body Keldysh Green's functions approach to ...
In this paper we apply a microscopic nonequilibrium many body Keldysh Green's functions approach to ...
The optical spectra of a quantum cascade laser structure under nonequilibrium conditions is studied ...
Intersubband semiconductor-Bloch equations are investigated by incorporating many-body Coulomb inter...
The theory of nonequilibrium Green functions allows for a quantitative modeling of quantum cascade l...
Quantum cascade lasers can be modeled within a hierarchy of different approaches: Standard rate equa...
The theory of nonequilibrium Green functions allows for a quantitative modeling of quantum cascade l...
In this paper we present further details of a predictive Keldysh nonequilibrium many body Green's fu...
A many-body theory based on nonequilibrium Green functions, in which transport and optics are treate...
In this review we summarize current challenges for THz quantum cascade laser development as well as ...
The effects of many-body coulomb interaction and non-parabolicity on optical gain of terahertz quant...
The effects of many-body coulomb interaction and non-parabolicity on optical gain of terahertz quant...
Nonequilibrium optical gain is computed for quantum cascade lasers. The Greens functions theory cons...
A many-body theory is used to compute optical absorption due to intersubband transitions in structur...
The optical spectra of a quantum cascade laser structure under nonequilibrium conditions is studied ...
In this paper we apply a microscopic nonequilibrium many body Keldysh Green's functions approach to ...
In this paper we apply a microscopic nonequilibrium many body Keldysh Green's functions approach to ...
The optical spectra of a quantum cascade laser structure under nonequilibrium conditions is studied ...
Intersubband semiconductor-Bloch equations are investigated by incorporating many-body Coulomb inter...
The theory of nonequilibrium Green functions allows for a quantitative modeling of quantum cascade l...
Quantum cascade lasers can be modeled within a hierarchy of different approaches: Standard rate equa...
The theory of nonequilibrium Green functions allows for a quantitative modeling of quantum cascade l...
In this paper we present further details of a predictive Keldysh nonequilibrium many body Green's fu...