Ultracold fermionic atoms are proposed to be used in 1D optical lattices to quantum simulate the electronic transport in quantum cascade laser (QCL) structures. The competition between the coherent tunneling among (and within) the wells and the dissipative decay at the basis of lasing is discussed. In order to validate the proposed simulation scheme, such competition is quantitatively addressed in a simplified 1D model. The existence of optimal relationships between the model parameters is shown, maximizing the particle current, the population inversion (or their product), and the stimulated emission rate. This substantiates the concept of emulating the QCL operation mechanisms in cold-atom optical lattice simulators, laying the groundwork for addressing open questions, such as the impact of electron–electron scattering and the origin of transport-induced noise, in the design of new-generation QCLs.
Quantum Simulating the Electron Transport in Quantum Cascade Laser Structures / Trombettoni A.; Scazza F.; Minardi F.; Roati G.; Cappelli F.; Consolino L.; Smerzi A.; De Natale P.. - In: ADVANCED QUANTUM TECHNOLOGIES. - ISSN 2511-9044. - STAMPA. - 4:10(2021), pp. 2100044.1-2100044.12. [10.1002/qute.202100044]
Quantum Simulating the Electron Transport in Quantum Cascade Laser Structures
Minardi F.
;
2021
Abstract
Ultracold fermionic atoms are proposed to be used in 1D optical lattices to quantum simulate the electronic transport in quantum cascade laser (QCL) structures. The competition between the coherent tunneling among (and within) the wells and the dissipative decay at the basis of lasing is discussed. In order to validate the proposed simulation scheme, such competition is quantitatively addressed in a simplified 1D model. The existence of optimal relationships between the model parameters is shown, maximizing the particle current, the population inversion (or their product), and the stimulated emission rate. This substantiates the concept of emulating the QCL operation mechanisms in cold-atom optical lattice simulators, laying the groundwork for addressing open questions, such as the impact of electron–electron scattering and the origin of transport-induced noise, in the design of new-generation QCLs.| File | Dimensione | Formato | |
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