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Paper detail

Hot-Band Absorption Can Mimic Entangled Two-Photon Absorption

It has been proposed that entangled two-photon absorption (E2PA) can be observed with up to 10 orders of magnitude lower photon flux than its classical counterpart. However, there is a significant controversy regarding the magnitude of this quantum enhancement in excitation efficiency. We investigated the fluorescence signals from Rhodamine 6G and LDS798 excited with a CW laser or an entangled photon pair source at 1060 nm. We observed a signal that originates from hot-band absorption (HBA), which is one-photon absorption from thermally-populated vibrational levels of the ground electronic state. This mechanism, which has not been previously discussed in the context of E2PA, produces a signal with a linear power dependence, as would be expected for entangled two-photon excited fluorescence (E2PEF). For the typical conditions under which E2PEF measurements are performed, contributions from the HBA process could lead to a several orders-of-magnitude overestimate of the quantum advantage for excitation efficiency.

preprint2022arXivOpen access
Alexander MikhaylovRyan N. WilsonKristen M. ParzuchowskiMichael D. MazurekCharles H. Camp JrMartin J. StevensRalph Jimenez
physics.chem-phquant-ph
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Alexander MikhaylovRyan N. WilsonKristen M. ParzuchowskiMichael D. MazurekCharles H. Camp JrMartin J. StevensRalph Jimenez

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