Photon Flux and Distance from the Source: Consequences for Quantum Communication

, , &
Foundations of Physics 44 (4):389-405 (2014)
  Copy   BIBTEX

Abstract

The paper explores the fundamental physical principles of quantum mechanics (in fact, quantum field theory) that limit the bit rate for long distances and examines the assumption used in this exploration that losses can be ignored. Propagation of photons in optical fibers is modelled using methods of quantum electrodynamics. We define the “photon duration” as the standard deviation of the photon arrival time; we find its asymptotics for long distances and then obtain the main result of the paper: the linear dependence of photon duration on the distance when losses can be ignored. This effect puts the limit to joint increasing of the photon flux and the distance from the source and it has consequences for quantum communication. Once quantum communication develops into a real technology (including essential decrease of losses in optical fibres), it would be appealing to engineers to increase both the photon flux and the distance. And here our “photon flux/distance effect” has to be taken into account. This effect also may set an additional constraint to the performance of a loophole free test of Bell’s type—to close jointly the detection and locality loopholes

Categories

Keywords

Reprint years

DOI

10.1007/s10701-014-9786-0

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,349

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Indistinguishability in one-photon and two-photon interference.L. Mandel - 1995 - Foundations of Physics 25 (2):211-218.
Photon wave-particle duality and virtual electromagnetic waves.C. Meis - 1997 - Foundations of Physics 27 (6):865-873.
A Relativistic Schrödinger-like Equation for a Photon and Its Second Quantization.Donald H. Kobe - 1999 - Foundations of Physics 29 (8):1203-1231.
The Feynman-Wheeler Perfect Absorber Theory in a New Light.B. G. Sidharth - 2010 - Foundations of Physics 40 (8):1134-1140.
Second-Order Photon-Photon.W. Ulrich - 1995 - In John Archibald Wheeler, Daniel M. Greenberger & Anton Zeilinger (eds.), Fundamental Problems in Quantum Theory: A Conference Held in Honor of Professor John A. Wheeler. New York Academy of Sciences.
Zero-value physical quantities.Yuri Balashov - 1999 - Synthese 119 (3):253-286.
Range of violations of bell’s inequality by entangled photon pairs entangled photon pairs.Fred Kronz - unknown
Statistical explanation in physics: The copenhagen interpretation.Richard Schlegel - 1970 - Synthese 21 (1):65 - 82.
The light clock: Error and implications. [REVIEW]Richard Schlegel - 1980 - Foundations of Physics 10 (3-4):345-351.
The effect of localization on interference. I. Calculated intensities for a feasible optical experiment.C. E. Engelke & C. W. Engelke - 1986 - Foundations of Physics 16 (9):905-916.
Experimental Realization of Popper's Experiment: Violation of the Uncertainty Principle? [REVIEW]Yoon-Ho Kim & Yanhua Shih - 1999 - Foundations of Physics 29 (12):1849-1861.
Practical Implementation of a Test of Event-Based Corpuscular Model as an Alternative to Quantum Mechanics.Sergey V. Polyakov, Fabrizio Piacentini, Paolo Traina, Ivo P. Degiovanni, Alan Migdall, Giorgio Brida & Marco Genovese - 2013 - Foundations of Physics 43 (8):913-922.
Complementarity in the Bohr-Einstein photon box.Dennis Dieks & Sander Lam - unknown
Experimental test of the effective-photon hypothesis.E. Panarella - 1977 - Foundations of Physics 7 (5-6):405-419.
Can Quantum Gravity be Exposed in the Laboratory?Jacob D. Bekenstein - 2014 - Foundations of Physics 44 (5):452-462.

Analytics

Added to PP
2014-03-25

Downloads
29 (#535,100)

6 months
8 (#352,434)

Historical graph of downloads
How can I increase my downloads?

Author's Profile

Citations of this work

Add more citations

References found in this work

Add more references