{
  "id": "1403.4687",
  "version": "v2",
  "published": "2014-03-19T04:10:39.000Z",
  "updated": "2014-09-16T02:47:35.000Z",
  "title": "Equivalence of wave-particle duality to entropic uncertainty",
  "authors": [
    "Patrick J. Coles",
    "Jędrzej Kaniewski",
    "Stephanie Wehner"
  ],
  "comment": "9 + 16 pages, 8 figures. v2 presents a more complete and more general framework for wave-particle duality relations, as well as a more detailed analysis of the literature",
  "categories": [
    "quant-ph"
  ],
  "abstract": "Interferometers capture a basic mystery of quantum mechanics: a single particle can exhibit wave behavior, yet that wave behavior disappears when one tries to determine the particle's path inside the interferometer. This idea has been formulated quantitively as an inequality, e.g., by Englert and Jaeger, Shimony, and Vaidman, which upper bounds the sum of the interference visibility and the path distinguishability. Such wave-particle duality relations (WPDRs) are often thought to be conceptually inequivalent to Heisenberg's uncertainty principle, although this has been debated. Here we show that WPDRs correspond precisely to a modern formulation of the uncertainty principle in terms of entropies, namely the min- and max-entropies. This observation unifies two fundamental concepts in quantum mechanics. Furthermore, it leads to a robust framework for deriving novel WPDRs by applying entropic uncertainty relations to interferometric models. As an illustration, we derive a novel relation that captures the coherence in a quantum beam splitter.",
  "revisions": [
    {
      "version": "v1",
      "updated": "2014-03-19T04:10:39.000Z",
      "abstract": "Interferometers capture a basic mystery of quantum mechanics: a single quantum particle can exhibit wave behavior, yet that wave behavior disappears when one tries to determine the particle's path inside the interferometer. This idea has been formulated quantitively as an inequality, e.g., by Englert and Jaeger, Shimony, and Vaidman, which upper bounds the sum of the interference visibility and the path distinguishability. Such wave-particle duality relations (WPDRs) are often thought to be conceptually inequivalent to Heisenberg's uncertainty principle, although this has been debated. Here we show that WPDRs correspond precisely to a modern formulation of the uncertainty principle in terms of entropies, namely the min- and max-entropies. This observation unifies two fundamental concepts in quantum mechanics. Furthermore, it leads to a robust framework for deriving novel WPDRs by applying entropic uncertainty relations to interferometric models. As an illustration, we derive a novel relation that captures the coherence in a quantum beam splitter.",
      "comment": "7 + 4 pages, 5 figures",
      "journal": null,
      "doi": null
    },
    {
      "version": "v2",
      "updated": "2014-09-16T02:47:35.000Z"
    }
  ],
  "analyses": {
    "keywords": [
      "quantum mechanics",
      "equivalence",
      "wave-particle duality relations",
      "quantum beam splitter",
      "heisenbergs uncertainty principle"
    ],
    "tags": [
      "journal article"
    ],
    "publication": {
      "doi": "10.1038/ncomms6814",
      "journal": "Nature Communications",
      "year": 2014,
      "month": "Dec",
      "volume": 5,
      "pages": 5814
    },
    "note": {
      "typesetting": "TeX",
      "pages": 16,
      "language": "en",
      "license": "arXiv",
      "status": "editable",
      "adsabs": "2014NatCo...5E5814C",
      "inspire": 1409192
    }
  }
}