Related papers: Impact of the exciton fine structure splitting and measurement orientations on the robustness of cryptographic keys generated via the quantum protocol E91

Impact of the exciton fine structure splitting and measurement orientations on the robustness of cryptographic keys generated via the quantum protocol E91

URL: http://arxiv.org/abs/2412.03753v1
Date: Wed, 04 Dec 2024 22:46:45 GMT
Title: Impact of the exciton fine structure splitting and measurement orientations on the robustness of cryptographic keys generated via the quantum protocol E91
Authors: Adrián F. Hernández-Borda, María P. Rojas-Sepúlveda, Hanz Y. Ramírez-Gómez,
Abstract summary: This work focuses on the performance of the E91 quantum key distribution protocol under the variation of two elements. We obtain analytical expressions for the protocol's secret key rate and Bell's parameter as functions of the studied phase and angles. Our results show that the performance of the quantum transmission is highly impacted by the product between the exciton lifetime and the quantum dot's fine structure splitting.
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Abstract: Photons and optical circuits are among the most promising platforms for implementation of quantum technologies, because of its potential use in quantum computing, quantum cryptography and long-distance quantum communication. One of the main requirements to achieve reliable quantum communications are on-demand sources of highly entangled photon pairs, and semiconductor quantum dots have emerged as prominent candidates to satisfy the necessary conditions of brightness and entanglement fidelity. However, in most cases the biexciton-exciton-vacuum cascade produces a pair of maximally polarization-entangled photons with a dephasing, due to the exciton fine structure splitting. This work focuses on the performance of the E91 quantum key distribution protocol under the variation of two elements: first, the phase in the input state when the protocol is implemented using entangled photons generated via the radiative cascade, and second, the relative directions of the polarization analyzers. We obtain analytical expressions for the protocol's secret key rate and Bell's parameter as functions of the studied phase and angles. Then, we validate those expressions by means of a quantum computational implementation with the IBM's API Qiskit. Our results show that the performance of the quantum transmission is highly impacted by the product between the exciton lifetime and the quantum dot's fine structure splitting and that such an impact may be modulated through the orientation of the polarizers. These findings provide important insight for the scalable implementation of quantum key distribution protocols with quantum dots as entanglement sources.

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