Paul C. A. Hagen, Mathieu Bozzio, Moritz Cygorek, Doris E. Reiter, Vollrath M. Axt
Published 2024-09-13Version 1
Semiconductor quantum dots are a versatile source of single photons with tunable properties to be used in quantum-cryptographic applications. A crucial figure of merit of the emitted photons is photon number coherence (PNC), which impacts the security of many quantum communication protocols. In the process of single-photon generation, the quantum dot as a solid-state object is subject to an interaction with phonons, which can therefore indirectly affect the PNC. In this paper, we elaborate on the origin of PNC in optically excited quantum dots and how it is affected by phonons. In contrast to the expectation that phonons always deteriorate coherence, PNC can be increased in a quantum dot-cavity system due to the electron-phonon interaction.
Nodal "ground states" and orbital textures in semiconductor quantum dots
Spin-Forster transfer in optically excited quantum dots
Comment on "Nonlinear photoluminescence spectra from a quantum dot-cavity system revisited" by Yao et al. and "Photoluminescence from Microcavities Strongly Coupled to Single Quantum Dots" by Ridolfo et al
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