2018
DOI: 10.1063/1.5004640
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Two-well quantum cascade laser optimization by non-equilibrium Green's function modelling

Abstract: We present a two-quantum well THz intersubband laser operating up to 192 K. The structure has been optimized with a non-equilibrium Green's function model. The result of this optimization was confirmed experimentally by growing, processing and measuring a number of proposed designs. At high temperature (T > 200 K), the simulations indicate that lasing fails due to a combination of electron-electron scattering, thermal backfilling, and, most importantly, re-absorption coming from broadened states.Terahertz quan… Show more

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Cited by 59 publications
(51 citation statements)
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“…The discrepancy between the optimized (nominal) structure and the best (3.5% thinner) structure (which is also better in the NEGF model under a detailed analysis) can be explained by the restrictions imposed to the optimization, since the best structure operates at a higher bias (56 mV/period) and photon energy (16.5 meV). In accordance with previous results 22 , including a rudimentary form of electron-electron scattering 29 in the model (not shown) the current density changes negligibly while the gain is almost halved and red shifted by 1 meV at 200 K.We also find that the temperature degradation of the presented design is dominated by level broadening. 22 Laser spectra with the device operating on a Peltier cooler were performed using a commercial FTIR (Bruker Vertex 80V) equipped with a DTGS room temperature detector, making such setup fully cryogenic free.…”
supporting
confidence: 92%
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“…The discrepancy between the optimized (nominal) structure and the best (3.5% thinner) structure (which is also better in the NEGF model under a detailed analysis) can be explained by the restrictions imposed to the optimization, since the best structure operates at a higher bias (56 mV/period) and photon energy (16.5 meV). In accordance with previous results 22 , including a rudimentary form of electron-electron scattering 29 in the model (not shown) the current density changes negligibly while the gain is almost halved and red shifted by 1 meV at 200 K.We also find that the temperature degradation of the presented design is dominated by level broadening. 22 Laser spectra with the device operating on a Peltier cooler were performed using a commercial FTIR (Bruker Vertex 80V) equipped with a DTGS room temperature detector, making such setup fully cryogenic free.…”
supporting
confidence: 92%
“…In accordance with previous results 22 , including a rudimentary form of electron-electron scattering 29 in the model (not shown) the current density changes negligibly while the gain is almost halved and red shifted by 1 meV at 200 K.We also find that the temperature degradation of the presented design is dominated by level broadening. 22 Laser spectra with the device operating on a Peltier cooler were performed using a commercial FTIR (Bruker Vertex 80V) equipped with a DTGS room temperature detector, making such setup fully cryogenic free. Spectra measured at different temperatures with a resolution of 0.2 cm −1 are reported in Fig.3(a).…”
supporting
confidence: 92%
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