We propose and experimentally demonstrate a general method allowing us to unravel microscopic noise events that affect a continuous quantum variable. Such unraveling is achieved by frequent measurements of a discrete variable coupled to the continuous one. The experimental realization involves photons traversing a noisy channel. There, their polarization, whose coupling to the photons’ spatial wave packet is subjected to stochastic noise, is frequently measured in the quantum Zeno regime. The measurements not only preserve the polarization state, but also enable the recording of the full noise statistics from the spatially resolved detection of the photons emerging from the channel. This method proves the possibility of employing photons as quantum noise sensors and robust carriers of information.
Sensing microscopic noise events by frequent quantum measurements / Virzi', Salvatore; Knoll, Laura T.; Avella, Alessio; Piacentini, Fabrizio; Gherardini, Stefano; Gramegna, Marco; Kurizki, Gershon; Kofman, Abraham G.; Degiovanni, IVO PIETRO; Genovese, Marco; Caruso, Filippo. - In: PHYSICAL REVIEW APPLIED. - ISSN 2331-7019. - (2024). [10.1103/PhysRevApplied.21.034014]
Sensing microscopic noise events by frequent quantum measurements
Salvatore Virzi';Laura T. Knoll;Alessio Avella;Fabrizio Piacentini;Marco Gramegna;Ivo Pietro Degiovanni;Marco Genovese;
2024
Abstract
We propose and experimentally demonstrate a general method allowing us to unravel microscopic noise events that affect a continuous quantum variable. Such unraveling is achieved by frequent measurements of a discrete variable coupled to the continuous one. The experimental realization involves photons traversing a noisy channel. There, their polarization, whose coupling to the photons’ spatial wave packet is subjected to stochastic noise, is frequently measured in the quantum Zeno regime. The measurements not only preserve the polarization state, but also enable the recording of the full noise statistics from the spatially resolved detection of the photons emerging from the channel. This method proves the possibility of employing photons as quantum noise sensors and robust carriers of information.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
