Feedforward-enhanced Fock state conversion with linear optics

• URL: http://arxiv.org/abs/2004.14436v1
• Date: Wed, 29 Apr 2020 18:58:02 GMT
• Title: Feedforward-enhanced Fock state conversion with linear optics
• Authors: Vojt\v{e}ch \v{S}varc, Josef Hlou\v{s}ek, Martina Nov\'akov\'a, Jarom\'ir Fiur\'a\v{s}ek, and Miroslav Je\v{z}ek
• Abstract summary: We propose an adaptive multi-photon subtraction scheme where a particular subtraction task is conditioned by all previous subtraction events. We experimentally demonstrate the core building block of the proposal by implementing a feedforward-assisted conversion of two-photon state to a single-photon state. The reported optimized photon subtraction scheme applies to a broad range of photonic states, including highly nonclassical Fock states and squeezed light.
• Score: 0.0
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: Engineering quantum states of light represents a crucial task in the vast majority of photonic quantum technology applications. Direct manipulation of the number of photons in the light signal, such as single-photon subtraction and addition, proved to be an efficient strategy for the task. Here we propose an adaptive multi-photon subtraction scheme where a particular subtraction task is conditioned by all previous subtraction events in order to maximize the probability of successful subtraction. We theoretically illustrate this technique on the model example of conversion of Fock states via photon subtraction. We also experimentally demonstrate the core building block of the proposal by implementing a feedforward-assisted conversion of two-photon state to a single-photon state. Our experiment combines two elementary photon subtraction blocks where the splitting ratio of the second subtraction beam splitter is affected by the measurement result from the first subtraction block in real time using an ultra-fast feedforward loop. The reported optimized photon subtraction scheme applies to a broad range of photonic states, including highly nonclassical Fock states and squeezed light, advancing the photonic quantum toolbox.

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