The Private Lives of Photons: asking particles where they spent the night
ORAL · Invited
Abstract
While photons famously don’t follow definite trajectories, there are questions one can ask – experimentally as well as theoretically – about where they have spent their time before being observed. This raises thorny issues about how to talk about the past of a quantum system. The interaction of a resonant laser with a cloud of two-level atoms is so well studied that one would hardly expect it to hold any more mystery, and yet it turns out to still have surprises in store when one considers the effect of post-selection.
I will describe an experiment studying optical nonlinearity at the single-photon level, giving particular attention to the novel effects observed when post-selecting on the final state of a photon. This apparatus enables us to probe how much time atoms are caused to spend in the excited state by a resonant photon. Specifically, we investigated whether the answer depends on whether the photon in question is transmitted or reflected. Not only is the answer yes, but the result for transmitted photons turned out to be quite unexpected. I will present theory and experiment supporting a provocative connection between the delay time experienced by a pulse and the time atoms spend in the excited state. Finally, I will address the question of how to think about a photon which is prepared in a narrow frequency mode, but later observed at a particular time.
• Observation of the nonlinear phase shift due to single post-selected photons, Amir Feizpour et al., Nat. Phys. 11, 905 (2015)
• How the Result of Counting One Photon Can Turn Out to Be a Value of 8, Matin Hallaji et al., Nat. Phys. 13, 540 (2017)
• Measuring the time atoms spend in the excited state due to a photon they do not absorb, Josiah Sinclair et al., PRX Quantum 3, 010314 (2022)
• How much time does a resonant photon spend as an atomic excitation before being transmitted?, Kyle Thompson et al., APL Quantum 2, 036108 (2025)
• Experimental evidence that a photon can spend a negative amount of time in an atom cloud, Daniela Angulo et al., PRL 136, 153601 (2026)
I will describe an experiment studying optical nonlinearity at the single-photon level, giving particular attention to the novel effects observed when post-selecting on the final state of a photon. This apparatus enables us to probe how much time atoms are caused to spend in the excited state by a resonant photon. Specifically, we investigated whether the answer depends on whether the photon in question is transmitted or reflected. Not only is the answer yes, but the result for transmitted photons turned out to be quite unexpected. I will present theory and experiment supporting a provocative connection between the delay time experienced by a pulse and the time atoms spend in the excited state. Finally, I will address the question of how to think about a photon which is prepared in a narrow frequency mode, but later observed at a particular time.
• Observation of the nonlinear phase shift due to single post-selected photons, Amir Feizpour et al., Nat. Phys. 11, 905 (2015)
• How the Result of Counting One Photon Can Turn Out to Be a Value of 8, Matin Hallaji et al., Nat. Phys. 13, 540 (2017)
• Measuring the time atoms spend in the excited state due to a photon they do not absorb, Josiah Sinclair et al., PRX Quantum 3, 010314 (2022)
• How much time does a resonant photon spend as an atomic excitation before being transmitted?, Kyle Thompson et al., APL Quantum 2, 036108 (2025)
• Experimental evidence that a photon can spend a negative amount of time in an atom cloud, Daniela Angulo et al., PRL 136, 153601 (2026)
*We acknowledge funding from NSERC, the Fetzer Franklin Fund, the QuEnSi quantum alliance, the ARC, and the John Templeton Foundation.
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Presenters
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Aephraim M Steinberg
- University of Toronto