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Main Authors: Martínez-Pons, J. -V. Vidal, Kim, S. -K., Behrens, M., Izquierdo-Molina, A., Rua, A. Menendez, Paçal, S., Ateş, S., Viña, L., Antón-Solanas, C.
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.10644
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author Martínez-Pons, J. -V. Vidal
Kim, S. -K.
Behrens, M.
Izquierdo-Molina, A.
Rua, A. Menendez
Paçal, S.
Ateş, S.
Viña, L.
Antón-Solanas, C.
author_facet Martínez-Pons, J. -V. Vidal
Kim, S. -K.
Behrens, M.
Izquierdo-Molina, A.
Rua, A. Menendez
Paçal, S.
Ateş, S.
Viña, L.
Antón-Solanas, C.
contents Color centers in hexagonal boron nitride (hBN) emerge as promising quantum light sources at room temperature, with potential applications in quantum communications, among others. The temporal coherence of emitted photons (i.e. their capacity to interfere and distribute photonic entanglement) is essential for many of these applications. Hence, it is crucial to study and determine the temporal coherence of this emission under different experimental conditions. In this work, we report the coherence time of the single photons emitted by an hBN defect in a nanocrystal at room temperature, measured via Michelson interferometry. The visibility of this interference vanishes when the temporal delay between the interferometer arms is a few hundred femtoseconds, highlighting that the phonon dephasing processes are four orders of magnitude faster than the spontaneous decay time of the emitter. We also analyze the single photon characteristics of the emission via correlation measurements, defect blinking dynamics, and its Debye-Waller factor. Our room temperature results highlight the presence of a strong phonon-electron coupling, suggesting the need to work at cryogenic temperatures to enable quantum photonic applications based on photon interference.
format Preprint
id arxiv_https___arxiv_org_abs_2505_10644
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Temporal coherence of single photons emitted by hexagonal Boron Nitride defects at room temperature
Martínez-Pons, J. -V. Vidal
Kim, S. -K.
Behrens, M.
Izquierdo-Molina, A.
Rua, A. Menendez
Paçal, S.
Ateş, S.
Viña, L.
Antón-Solanas, C.
Quantum Physics
Mesoscale and Nanoscale Physics
Color centers in hexagonal boron nitride (hBN) emerge as promising quantum light sources at room temperature, with potential applications in quantum communications, among others. The temporal coherence of emitted photons (i.e. their capacity to interfere and distribute photonic entanglement) is essential for many of these applications. Hence, it is crucial to study and determine the temporal coherence of this emission under different experimental conditions. In this work, we report the coherence time of the single photons emitted by an hBN defect in a nanocrystal at room temperature, measured via Michelson interferometry. The visibility of this interference vanishes when the temporal delay between the interferometer arms is a few hundred femtoseconds, highlighting that the phonon dephasing processes are four orders of magnitude faster than the spontaneous decay time of the emitter. We also analyze the single photon characteristics of the emission via correlation measurements, defect blinking dynamics, and its Debye-Waller factor. Our room temperature results highlight the presence of a strong phonon-electron coupling, suggesting the need to work at cryogenic temperatures to enable quantum photonic applications based on photon interference.
title Temporal coherence of single photons emitted by hexagonal Boron Nitride defects at room temperature
topic Quantum Physics
Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2505.10644