English

Wavefunction collapse through backaction of counting weakly interacting photons

Quantum Physics 2016-04-05 v4

Abstract

We apply the formalism of quantum measurement theory to the idealized measurement of the position of a particle with an optical interferometer, finding that the backaction of counting entangled photons systematically collapses the particle's wavefunction toward a narrow Gaussian wavepacket at the location xestx_\mathrm{est} determined by the measurement without appeal to environmental decoherence or other spontaneous collapse mechanism. Further, the variance in the particle's position, as calculated from the post-measurement wavefunction agrees precisely with shot-noise limited uncertainty of the measured xestx_\mathrm{est}. Both the identification of the absolute square of the particle's initial wavefunction as the probability density for xestx_\mathrm{est} and the de Broglie hypothesis emerge as consequences of interpreting the intensity of the optical field as proportional to the probability of detecting a photon. Linear momentum information that is encoded in the particle's initial wavefunction survives the measurement, and the pre-measurement expectation values are preserved in the ensemble average.

Keywords

Cite

@article{arxiv.1601.01880,
  title  = {Wavefunction collapse through backaction of counting weakly interacting photons},
  author = {Lee E. Harrell},
  journal= {arXiv preprint arXiv:1601.01880},
  year   = {2016}
}

Comments

7 pages, 1 figure

R2 v1 2026-06-22T12:25:33.184Z