Your search keyword '"Wilksen, Steffen"' showing total 2 results

1. Impact of phonon lifetimes on the single-photon indistinguishability in quantum emitters based on 2D materials

Author

Steinhoff, Alexander, Wilksen, Steffen, Solovev, Ivan, Schneider, Christian, and Gies, Christopher

Subjects

Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Localized excitons in two-dimensional (2D) materials are considered as promising sources of single photons on demand. The photon indistinguishability as key figure of merit for quantum information processing is strongly influenced by the coupling of charge excitations to lattice vibrations of the surrounding semiconductor material. Here, we quantify the impact of exciton-acoustic-phonon-interaction and cavity QED effects on photon indistinguishability in a Hong-Ou-Mandel setup by solving fully quantum mechanical equations for the coupled QD-cavity-phonon system including non-Markovian effects. We find a strong reduction of indistinguishability compared to 3D systems due to increased exciton-phonon coupling efficiency. Moreover, we show that the coherence properties of photons are significantly influenced by the finite phonon lifetime in the surrounding material giving rise to pure dephasing. Only if these limitations can be overcome, localized excitons in 2D semiconductors can become a new avenue for quantum light sources.

Published

2025

2. Gate-based protocol simulations for quantum repeaters using quantum-dot molecules in switchable electric fields

Author

Wilksen, Steffen, Lohof, Frederik, Willmann, Isabell, Bopp, Frederik, Lienhart, Michelle, Thalacker, Christopher, Finley, Jonathan, Florian, Matthias, and Gies, Christopher

Subjects

Quantum Physics, Condensed Matter - Mesoscale and Nanoscale Physics

Abstract

Electrically controllable quantum-dot molecules (QDMs) are a promising platform for deterministic entanglement generation and, as such, a resource for quantum-repeater networks. We develop a microscopic open-quantum-systems approach based on a time-dependent Bloch-Redfield equation to model the generation of entangled spin states with high fidelity. The state preparation is a crucial step in a protocol for deterministic entangled-photon-pair generation that we propose for quantum repeater applications. Our theory takes into account the quantum-dot molecules' electronic properties that are controlled by time-dependent electric fields as well as dissipation due to electron-phonon interaction. We quantify the transition between adiabatic and non-adiabatic regimes, which provides insights into the dynamics of adiabatic control of QDM charge states in the presence of dissipative processes. From this, we infer the maximum speed of entangled-state preparation under different experimental conditions, which serves as a first step towards simulation of attainable entangled photon-pair generation rates. The developed formalism opens the possibility for device-realistic descriptions of repeater protocol implementations., Comment: 12 pages, 11 figures

Published

2023