The direct test of the absence of the "quantum vampire's" shadow with use of thermal light

Counterintuitive nature of quantum physics leads to a number of paradoxes. One of them is a "quantum vampire" effect [1] consisting in the fact, that photon annihilation in a part of a large beam doesn't change the shape of the beam profile (i. e., doesn't cast a shadow), but may...

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Hauptverfasser: Katamadze, K G, Kovlakov, E V, Avosopiants, G V, Kulik, S P
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description Counterintuitive nature of quantum physics leads to a number of paradoxes. One of them is a "quantum vampire" effect [1] consisting in the fact, that photon annihilation in a part of a large beam doesn't change the shape of the beam profile (i. e., doesn't cast a shadow), but may change the total beam intensity. Previously this effect was demonstrated just in a simplified double-mode regime [1,2]. In the current paper the direct test of shadow absence after the photon annihilation has been performed with use of thermal state of light at the input.
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subjects Paradoxes
Physics - Optics
Physics - Quantum Physics
Quantum theory
Shadows
title The direct test of the absence of the "quantum vampire's" shadow with use of thermal light
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