Jump to content

Pusey–Barrett–Rudolph theorem: Difference between revisions

Add links
From Wikipedia, the free encyclopedia
Browse history interactively
← Previous edit
Content deleted Content added
VisualWikitext
Oxysh (talk | contribs)
28 edits
Theorem: More description of the theorem in the opening section, including comparison to Bell and Kochen–Specker theorems. Added a "See also" section. Moved Valentini quote to introductory section. Removed mention of theorem being known as "Pusey's theorem": I can only find one instance of this online in a blog and not in any published articles; as a scientific work I think proper accreditation to all authors should be encouraged.
emphasis on local
 
(19 intermediate revisions by 16 users not shown)
Line 1: Line 1:
{{Short description|Theorem pertaining to the ontology of quantum mechanics}}
The '''PBR theorem<ref name="NatPhys2012" />''' is a [[no-go theorem]] in [[quantum foundations]] due to Matthew Pusey, Jonathan Barrett, and [[Terry Rudolph]] (for whom the theorem is named). It has particular significance for how one may interpret the nature of the [[quantum state]].
The '''Pusey–Barrett–Rudolph''' ('''PBR''') '''theorem'''<ref name="NatPhys2012" /> is a [[no-go theorem]] in [[quantum foundations]] due to Matthew Pusey, Jonathan Barrett, and [[Terry Rudolph]] (for whom the theorem is named) in 2012. It has particular significance for how one may interpret the nature of the [[quantum state]].


With respect to certain realist [[Hidden-variable theory|hidden variable theories]] that attempt to explain the predictions of [[quantum mechanics]], the theorem rules that pure quantum states must be "ontic" in the sense that they correspond directly to states of reality, rather than "epistemic" in the sense that they represents probabilistic or incomplete states of knowledge about reality.
With respect to certain realist [[Hidden-variable theory|hidden variable theories]] that attempt to explain the predictions of [[quantum mechanics]], the theorem rules that pure quantum states must be "ontic" in the sense that they correspond directly to states of reality, rather than "epistemic" in the sense that they represent probabilistic or incomplete states of knowledge about reality.


The PBR theorem may also be compared with other no-go theorems like [[Bell's theorem]] and the [[Kochen–Specker theorem|Bell–Kochen–Specker theorem]], which, respectively, rule out the possibility of explaining the predictions of quantum mechanics with local hidden variable theories and noncontextual hidden variable theories. Similarly, the PBR theorem could be said to rule out ''preparation independent'' hidden variable theories, in which quantum states that are prepared independently have independent hidden variable descriptions.
The PBR theorem may also be compared with other no-go theorems like [[Bell's theorem]] and the [[Kochen–Specker theorem|Bell–Kochen–Specker theorem]], which, respectively, rule out the possibility of explaining the predictions of quantum mechanics with ''local'' hidden variable theories and noncontextual hidden variable theories. Similarly, the PBR theorem could be said to rule out ''preparation independent'' hidden variable theories, in which quantum states that are prepared independently have independent hidden variable descriptions.


This result was cited by theoretical physicist [[Antony Valentini]] as "the most important general theorem relating to the foundations of quantum mechanics since [[Bell's theorem]]".<ref>{{cite journal|last=Reich|first=Eugenie Samuel|date=17 November 2011|title=Quantum theorem shakes foundations|url=http://www.nature.com/news/quantum-theorem-shakes-foundations-1.9392|journal=Nature|doi=10.1038/nature.2011.9392|accessdate=20 November 2011}}</ref>
This result was cited by theoretical physicist [[Antony Valentini]] as "the most important general theorem relating to the foundations of quantum mechanics since [[Bell's theorem]]".<ref>{{cite journal|last=Reich|first=Eugenie Samuel|date=17 November 2011|title=Quantum theorem shakes foundations|url=http://www.nature.com/news/quantum-theorem-shakes-foundations-1.9392|journal=Nature|doi=10.1038/nature.2011.9392|s2cid=211836537 |access-date=20 November 2011}}</ref>


== Theorem ==
== Theorem ==
This theorem, which first appeared as an [[arXiv]] preprint<ref>{{cite arXiv |last1= Pusey |first1=Matthew F. |last2=Barrett |first2=Jonathan |last3=Rudolph |first3=Terry |eprint=1111.3328v1 |class=quant-ph |year=2011 |title=The quantum state cannot be interpreted statistically}}</ref> and was subsequently published in ''[[Nature Physics]]''<ref name="NatPhys2012">{{cite journal | last1 = Pusey | first1 = M. F. | last2 = Barrett | first2 = J. | last3 = Rudolph | first3 = T. | year = 2012 | title = On the reality of the quantum state | url = | journal = Nature Physics | volume = 8 | issue = 6| pages = 475–478 | doi = 10.1038/nphys2309 | arxiv = 1111.3328 | bibcode = 2012NatPh...8..476P }}</ref>, concerns the interpretational status of pure quantum states. Under the classification of hidden variable models of Harrigan and Spekkens,<ref>{{Cite journal|last=Harrigan|first=Nicholas|last2=Spekkens|first2=Robert W.|date=2010|title=Einstein, Incompleteness, and the Epistemic View of Quantum States|url=http://link.springer.com/10.1007/s10701-009-9347-0|journal=Foundations of Physics|language=en|volume=40|issue=2|pages=125–157|arxiv=0706.2661|doi=10.1007/s10701-009-9347-0|issn=0015-9018|via=}}</ref> the interpretation of the quantum wavefunction <math>|\psi\rangle</math>can be categorized as either ''ψ''-ontic if "every complete physical state ontic state in the theory is consistent with only one pure quantum state" and ''ψ-''epistemic "if there exist ontic states that are consistent with more than one pure quantum state." The PBR theorem proves that either the quantum state <math>|\psi\rangle</math>is ''ψ''-ontic, or else non-[[quantum entanglement|entangled]] quantum states violate the assumption of preparation independence, which would entail [[action at a distance (physics)|action at a distance]].
This theorem, which first appeared as an [[arXiv]] preprint<ref>{{cite arXiv |last1= Pusey |first1=Matthew F. |last2=Barrett |first2=Jonathan |last3=Rudolph |first3=Terry |eprint=1111.3328v1 |class=quant-ph |year=2011 |title=The quantum state cannot be interpreted statistically}}</ref> and was subsequently published in ''[[Nature Physics]]'',<ref name="NatPhys2012">{{cite journal | last1 = Pusey | first1 = M. F. | last2 = Barrett | first2 = J. | last3 = Rudolph | first3 = T. | year = 2012 | title = On the reality of the quantum state | journal = Nature Physics | volume = 8 | issue = 6| pages = 475–478 | doi = 10.1038/nphys2309 | arxiv = 1111.3328 | bibcode = 2012NatPh...8..476P | s2cid = 14618942 }}</ref> concerns the interpretational status of pure quantum states. Under the classification of hidden variable models of Harrigan and Spekkens,<ref>{{Cite journal|last1=Harrigan|first1=Nicholas|author2-link=Robert Spekkens|last2=Spekkens|first2=Robert W.|date=2010|title=Einstein, Incompleteness, and the Epistemic View of Quantum States|journal=Foundations of Physics|language=en|volume=40|issue=2|pages=125–157|arxiv=0706.2661|doi=10.1007/s10701-009-9347-0|issn=0015-9018|bibcode=2010FoPh...40..125H|s2cid=32755624 }}</ref> the interpretation of the quantum wavefunction <math>|\psi\rangle</math> can be categorized as either ''ψ''-ontic if "every complete physical state or ontic state in the theory is consistent with only one pure quantum state" and ''ψ-''epistemic "if there exist ontic states that are consistent with more than one pure quantum state." The PBR theorem proves that either the quantum state <math>|\psi\rangle</math> is ''ψ''-ontic, or else non-[[quantum entanglement|entangled]] quantum states violate the assumption of preparation independence, which would entail [[action at a distance (physics)|action at a distance]].


{{Quote|text=In conclusion, we have presented a [[no-go theorem]], which - modulo assumptions - shows that models in which the quantum state is interpreted as mere [[quantum information|information]] about an objective physical state of a system cannot reproduce the predictions of quantum theory. The result is in the same spirit as Bell’s theorem, which states that no local theory can reproduce the predictions of quantum theory.|author=Matthew F. Pusey, Jonathan Barrett, and Terry Rudolph|source="On the reality of the quantum state", ''Nature Physics'' '''8''', 475-478 (2012)}}
{{Quote|text=In conclusion, we have presented a [[no-go theorem]], which—modulo assumptions—shows that models in which the quantum state is interpreted as mere [[quantum information|information]] about an objective physical state of a system cannot reproduce the predictions of quantum theory. The result is in the same spirit as Bell’s theorem, which states that no local theory can reproduce the predictions of quantum theory.|author=Matthew F. Pusey, Jonathan Barrett, and Terry Rudolph|source="On the reality of the quantum state", ''Nature Physics'' '''8''', 475-478 (2012)}}


==See also==
==See also==
Line 22: Line 23:


==External links==
==External links==
* {{cite web |url=http://blogs.discovermagazine.com/cosmicvariance/2011/11/18/guest-post-david-wallace-on-the-physicality-of-the-quantum-state/ |title=Guest Post: David Wallace on the Physicality of the Quantum State |author=David Wallace |date=18 November 2011 |work=Discover Magazine (blog) |publisher= Kalmbach Publishing Co |accessdate=20 November 2011}}
* {{cite web |url=http://blogs.discovermagazine.com/cosmicvariance/2011/11/18/guest-post-david-wallace-on-the-physicality-of-the-quantum-state/ |title=Guest Post: David Wallace on the Physicality of the Quantum State |author=David Wallace |date=18 November 2011 |work=Discover Magazine (blog) |publisher= Kalmbach Publishing Co |access-date=20 November 2011}}
* {{cite web |url=http://science.slashdot.org/story/11/11/18/1742222/study-says-quantum-wavefunction-is-a-real-physical-object |title=Study Says Quantum Wavefunction Is a Real Physical Object |date=18 November 2011 |work=Slashdot |accessdate=20 November 2011}}
* {{cite web |url=http://science.slashdot.org/story/11/11/18/1742222/study-says-quantum-wavefunction-is-a-real-physical-object |title=Study Says Quantum Wavefunction Is a Real Physical Object |date=18 November 2011 |work=Slashdot |access-date=20 November 2011}}
* {{cite web |url=http://mattleifer.info/2011/11/20/can-the-quantum-state-be-interpreted-statistically/ |title=Can the quantum state be interpreted statistically? |author=Matt Leifer |work=Mathematics — Physics — Quantum Theory blog |date=20 November 2011 |accessdate=24 November 2011}}
* {{cite web |url=http://mattleifer.info/2011/11/20/can-the-quantum-state-be-interpreted-statistically/ |title=Can the quantum state be interpreted statistically? |author=Matt Leifer |work=Mathematics — Physics — Quantum Theory blog |date=20 November 2011 |access-date=24 November 2011}}
* {{cite journal
* {{cite journal
| last = Leifer
| last = Leifer
| first = Matt
| first = Matt
| authorlink =
| title = Is the quantum state real? An extended review of ψ-ontology theorems
| title = Is the quantum state real? An extended review of ψ-ontology theorems
| journal = Quanta
| journal = Quanta
Line 34: Line 34:
| issue = 1
| issue = 1
| pages = 67–155
| pages = 67–155
| publisher =
| location =
| language =
| jstor =
| issn = 1314-7374
| issn = 1314-7374
| doi = 10.12743/quanta.v3i1.22
| doi = 10.12743/quanta.v3i1.22
| id =
| mr =
| zbl =
| jfm =
| year = 2014
| year = 2014
| arxiv = 1409.1570
| arxiv = 1409.1570
| s2cid = 119295895
}}
}}

* {{cite web |url=http://www3.imperial.ac.uk/controlledquantumdynamics/people/students/cohortone/matthewpusey |title=Matthew Pusey at Imperial College |author=Matt Pusey |work=Imperial College London |date=30 November 2011 |accessdate=30 November 2011}}
{{Quantum computing}}


[[Category:Quantum information science]]
[[Category:Quantum information science]]
[[Category:Theorems in quantum physics]]
[[Category:Theorems in quantum mechanics]]
[[Category:Hidden variable theory]]
[[Category:Hidden variable theory]]
[[Category:No-go theorems]]

Latest revision as of 16:38, 9 May 2024

The Pusey–Barrett–Rudolph (PBR) theorem[1] is a no-go theorem in quantum foundations due to Matthew Pusey, Jonathan Barrett, and Terry Rudolph (for whom the theorem is named) in 2012. It has particular significance for how one may interpret the nature of the quantum state.

With respect to certain realist hidden variable theories that attempt to explain the predictions of quantum mechanics, the theorem rules that pure quantum states must be "ontic" in the sense that they correspond directly to states of reality, rather than "epistemic" in the sense that they represent probabilistic or incomplete states of knowledge about reality.

The PBR theorem may also be compared with other no-go theorems like Bell's theorem and the Bell–Kochen–Specker theorem, which, respectively, rule out the possibility of explaining the predictions of quantum mechanics with local hidden variable theories and noncontextual hidden variable theories. Similarly, the PBR theorem could be said to rule out preparation independent hidden variable theories, in which quantum states that are prepared independently have independent hidden variable descriptions.

This result was cited by theoretical physicist Antony Valentini as "the most important general theorem relating to the foundations of quantum mechanics since Bell's theorem".[2]

Theorem

[edit]

This theorem, which first appeared as an arXiv preprint[3] and was subsequently published in Nature Physics,[1] concerns the interpretational status of pure quantum states. Under the classification of hidden variable models of Harrigan and Spekkens,[4] the interpretation of the quantum wavefunction can be categorized as either ψ-ontic if "every complete physical state or ontic state in the theory is consistent with only one pure quantum state" and ψ-epistemic "if there exist ontic states that are consistent with more than one pure quantum state." The PBR theorem proves that either the quantum state is ψ-ontic, or else non-entangled quantum states violate the assumption of preparation independence, which would entail action at a distance.

In conclusion, we have presented a no-go theorem, which—modulo assumptions—shows that models in which the quantum state is interpreted as mere information about an objective physical state of a system cannot reproduce the predictions of quantum theory. The result is in the same spirit as Bell’s theorem, which states that no local theory can reproduce the predictions of quantum theory.

— Matthew F. Pusey, Jonathan Barrett, and Terry Rudolph, "On the reality of the quantum state", Nature Physics 8, 475-478 (2012)

See also

[edit]

References

[edit]
  1. ^ a b Pusey, M. F.; Barrett, J.; Rudolph, T. (2012). "On the reality of the quantum state". Nature Physics. 8 (6): 475–478. arXiv:1111.3328. Bibcode:2012NatPh...8..476P. doi:10.1038/nphys2309. S2CID 14618942.
  2. ^ Reich, Eugenie Samuel (17 November 2011). "Quantum theorem shakes foundations". Nature. doi:10.1038/nature.2011.9392. S2CID 211836537. Retrieved 20 November 2011.
  3. ^ Pusey, Matthew F.; Barrett, Jonathan; Rudolph, Terry (2011). "The quantum state cannot be interpreted statistically". arXiv:1111.3328v1 [quant-ph].
  4. ^ Harrigan, Nicholas; Spekkens, Robert W. (2010). "Einstein, Incompleteness, and the Epistemic View of Quantum States". Foundations of Physics. 40 (2): 125–157. arXiv:0706.2661. Bibcode:2010FoPh...40..125H. doi:10.1007/s10701-009-9347-0. ISSN 0015-9018. S2CID 32755624.
[edit]
Retrieved from "https://en.wikipedia.org/enwiki/w/index.php?title=Pusey–Barrett–Rudolph_theorem&oldid=1223058415"