Comparative analysis of quantum cascade laser modeling based on density matrices and non-equilibrium Green's functions

Martin Franckie; J. M. Wolf; V. Trinite; V. Liverini; J. Faist; G. Maisons; M. Carras; R. Aidam; R. Ostendorf; Andreas Wacker

doi:10.1063/1.4895123

Comparative analysis of quantum cascade laser modeling based on density matrices and non-equilibrium Green's functions

Martin Franckie, J. M. Wolf, V. Trinite, V. Liverini, J. Faist, G. Maisons, M. Carras, R. Aidam, R. Ostendorf, Andreas Wacker

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Abstract

We study the operation of an 8.5 mu m quantum cascade laser based on GaInAs/AlInAs lattice matched to InP using three different simulation models based on density matrix (DM) and non-equilibrium Green's function (NEGF) formulations. The latter advanced scheme serves as a validation for the simpler DM schemes and, at the same time, provides additional insight, such as the temperatures of the sub-band carrier distributions. We find that for the particular quantum cascade laser studied here, the behavior is well described by simple quantum mechanical estimates based on Fermi's golden rule. As a consequence, the DM model, which includes second order currents, agrees well with the NEGF results. Both these simulations are in accordance with previously reported data and a second regrown device. (C) 2014 AIP Publishing LLC.

Original language	English
Article number	103106
Journal	Applied Physics Letters
Volume	105
Issue number	10
DOIs	https://doi.org/10.1063/1.4895123
Publication status	Published - 2014

Subject classification (UKÄ)

Condensed Matter Physics

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10.1063/1.4895123

apl2014LindskogFinal published version, 1.11 MB

Modeling Quantum Cascade Lasers: the Challenge of Infra-Red Devices
Franckie, M. (PI)
2012/05/20 → 2016/05/13
Project: Dissertation

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abstract = "We study the operation of an 8.5 mu m quantum cascade laser based on GaInAs/AlInAs lattice matched to InP using three different simulation models based on density matrix (DM) and non-equilibrium Green's function (NEGF) formulations. The latter advanced scheme serves as a validation for the simpler DM schemes and, at the same time, provides additional insight, such as the temperatures of the sub-band carrier distributions. We find that for the particular quantum cascade laser studied here, the behavior is well described by simple quantum mechanical estimates based on Fermi's golden rule. As a consequence, the DM model, which includes second order currents, agrees well with the NEGF results. Both these simulations are in accordance with previously reported data and a second regrown device. (C) 2014 AIP Publishing LLC.",

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doi = "10.1063/1.4895123",

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publisher = "American Institute of Physics (AIP)",

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T1 - Comparative analysis of quantum cascade laser modeling based on density matrices and non-equilibrium Green's functions

AU - Franckie, Martin

AU - Wolf, J. M.

AU - Trinite, V.

AU - Liverini, V.

AU - Faist, J.

AU - Maisons, G.

AU - Carras, M.

AU - Aidam, R.

AU - Ostendorf, R.

AU - Wacker, Andreas

PY - 2014

Y1 - 2014

N2 - We study the operation of an 8.5 mu m quantum cascade laser based on GaInAs/AlInAs lattice matched to InP using three different simulation models based on density matrix (DM) and non-equilibrium Green's function (NEGF) formulations. The latter advanced scheme serves as a validation for the simpler DM schemes and, at the same time, provides additional insight, such as the temperatures of the sub-band carrier distributions. We find that for the particular quantum cascade laser studied here, the behavior is well described by simple quantum mechanical estimates based on Fermi's golden rule. As a consequence, the DM model, which includes second order currents, agrees well with the NEGF results. Both these simulations are in accordance with previously reported data and a second regrown device. (C) 2014 AIP Publishing LLC.

AB - We study the operation of an 8.5 mu m quantum cascade laser based on GaInAs/AlInAs lattice matched to InP using three different simulation models based on density matrix (DM) and non-equilibrium Green's function (NEGF) formulations. The latter advanced scheme serves as a validation for the simpler DM schemes and, at the same time, provides additional insight, such as the temperatures of the sub-band carrier distributions. We find that for the particular quantum cascade laser studied here, the behavior is well described by simple quantum mechanical estimates based on Fermi's golden rule. As a consequence, the DM model, which includes second order currents, agrees well with the NEGF results. Both these simulations are in accordance with previously reported data and a second regrown device. (C) 2014 AIP Publishing LLC.

U2 - 10.1063/1.4895123

DO - 10.1063/1.4895123

M3 - Article

SN - 0003-6951

VL - 105

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 10

M1 - 103106

ER -

Comparative analysis of quantum cascade laser modeling based on density matrices and non-equilibrium Green's functions

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Modeling Quantum Cascade Lasers: the Challenge of Infra-Red Devices

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