Entanglement of quantum clocks through gravity

Esteban Castro Ruiz; Flaminia Giacomini; Caslav Brukner

doi:10.1073/pnas.1616427114

Entanglement of quantum clocks through gravity

Esteban Castro Ruiz (Corresponding author), Flaminia Giacomini, Caslav Brukner

Quantum Optics, Quantum Nanophysics and Quantum Information

Publications: Contribution to journal › Article › Peer Reviewed

Abstract

In general relativity, the picture of space-time assigns an ideal clock to each world line. Being ideal, gravitational effects due to these clocks are ignored and the flow of time according to one clock is not affected by the presence of clocks along nearby world lines. However, if time is defined operationally, as a pointer position of a physical clock that obeys the principles of general relativity and quantum mechanics, such a picture is, at most, a convenient fiction. Specifically, we show that the general relativistic mass-energy equivalence implies gravitational interaction between the clocks, whereas the quantum mechanical superposition of energy eigenstates leads to a nonfixed metric background. Based only on the assumption that both principles hold in this situation, we show that the clocks necessarily get entangled through time dilation effect, which eventually leads to a loss of coherence of a single clock. Hence, the time as measured by a single clock is not well defined. However, the general relativistic notion of time is recovered in the classical limit of clocks.

Original language	English
Pages (from-to)	E2303-E2309
Number of pages	7
Journal	Proceedings of the National Academy of Sciences of the United States of America (PNAS)
Volume	114
Issue number	12
DOIs	https://doi.org/10.1073/pnas.1616427114
Publication status	Published - 21 Mar 2017

Funding

We thank F. Costa, A. Feix, P. Hoehn, W. Wieland, and M. Zych for interesting discussions. We acknowledge support from the John Templeton Foundation, Project 60609, "Quantum Causal Structures," from the research platform "Testing Quantum and Gravity Interface with Single Photons" (TURIS), and the Austrian Science Fund (FWF) through the special research program " Foundations and Applications of Quantum Science" (FoQuS), the doctoral program "Complex Quantum Systems" (CoQuS) under Project W1210-N25, and Individual Project 24621.

Austrian Fields of Science 2012

103025 Quantum mechanics
103028 Theory of relativity

Keywords

quantum clocks
entanglement
gravity c
classical limit
SPACE-TIME DISTANCES
LIMITATIONS
EVOLUTION
Quantum clocks
Entanglement
Classical limit
Gravity

Access to Document

10.1073/pnas.1616427114

Cite this

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title = "Entanglement of quantum clocks through gravity",

abstract = "In general relativity, the picture of space-time assigns an ideal clock to each world line. Being ideal, gravitational effects due to these clocks are ignored and the flow of time according to one clock is not affected by the presence of clocks along nearby world lines. However, if time is defined operationally, as a pointer position of a physical clock that obeys the principles of general relativity and quantum mechanics, such a picture is, at most, a convenient fiction. Specifically, we show that the general relativistic mass-energy equivalence implies gravitational interaction between the clocks, whereas the quantum mechanical superposition of energy eigenstates leads to a nonfixed metric background. Based only on the assumption that both principles hold in this situation, we show that the clocks necessarily get entangled through time dilation effect, which eventually leads to a loss of coherence of a single clock. Hence, the time as measured by a single clock is not well defined. However, the general relativistic notion of time is recovered in the classical limit of clocks.",

keywords = "quantum clocks, entanglement, gravity c, classical limit, SPACE-TIME DISTANCES, LIMITATIONS, EVOLUTION, Quantum clocks, Entanglement, Classical limit, Gravity",

author = "Ruiz, \{Esteban Castro\} and Flaminia Giacomini and Caslav Brukner",

note = "Funding Information: We thank F. Costa, A. Feix, P. Hoehn, W. Wieland, and M. Zych for interesting discussions. We acknowledge support from the John Templeton Foundation, Project 60609, {"}Quantum Causal Structures,{"} from the research platform {"}Testing Quantum and Gravity Interface with Single Photons{"} (TURIS), and the Austrian Science Fund (FWF) through the special research program {"}Foundations and Applications of Quantum Science{"} (FoQuS), the doctoral program {"}Complex Quantum Systems{"} (CoQuS) under Project W1210-N25, and Individual Project 24621.",

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AU - Ruiz, Esteban Castro

AU - Giacomini, Flaminia

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N1 - Funding Information: We thank F. Costa, A. Feix, P. Hoehn, W. Wieland, and M. Zych for interesting discussions. We acknowledge support from the John Templeton Foundation, Project 60609, "Quantum Causal Structures," from the research platform "Testing Quantum and Gravity Interface with Single Photons" (TURIS), and the Austrian Science Fund (FWF) through the special research program "Foundations and Applications of Quantum Science" (FoQuS), the doctoral program "Complex Quantum Systems" (CoQuS) under Project W1210-N25, and Individual Project 24621.

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N2 - In general relativity, the picture of space-time assigns an ideal clock to each world line. Being ideal, gravitational effects due to these clocks are ignored and the flow of time according to one clock is not affected by the presence of clocks along nearby world lines. However, if time is defined operationally, as a pointer position of a physical clock that obeys the principles of general relativity and quantum mechanics, such a picture is, at most, a convenient fiction. Specifically, we show that the general relativistic mass-energy equivalence implies gravitational interaction between the clocks, whereas the quantum mechanical superposition of energy eigenstates leads to a nonfixed metric background. Based only on the assumption that both principles hold in this situation, we show that the clocks necessarily get entangled through time dilation effect, which eventually leads to a loss of coherence of a single clock. Hence, the time as measured by a single clock is not well defined. However, the general relativistic notion of time is recovered in the classical limit of clocks.

AB - In general relativity, the picture of space-time assigns an ideal clock to each world line. Being ideal, gravitational effects due to these clocks are ignored and the flow of time according to one clock is not affected by the presence of clocks along nearby world lines. However, if time is defined operationally, as a pointer position of a physical clock that obeys the principles of general relativity and quantum mechanics, such a picture is, at most, a convenient fiction. Specifically, we show that the general relativistic mass-energy equivalence implies gravitational interaction between the clocks, whereas the quantum mechanical superposition of energy eigenstates leads to a nonfixed metric background. Based only on the assumption that both principles hold in this situation, we show that the clocks necessarily get entangled through time dilation effect, which eventually leads to a loss of coherence of a single clock. Hence, the time as measured by a single clock is not well defined. However, the general relativistic notion of time is recovered in the classical limit of clocks.

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Entanglement of quantum clocks through gravity

Abstract

Funding

Austrian Fields of Science 2012

Keywords

Access to Document

Other files and links

FoQuS III - P07: Quantum entanglement in higher-dimensional Hilbert spaces: foundations and applications

CoQuS: Complex Quantum Systems

Cite this

Entanglement of quantum clocks through gravity

Abstract

Funding

Austrian Fields of Science 2012

Keywords

Access to Document

Other files and links

Projects

FoQuS III - P07: Quantum entanglement in higher-dimensional Hilbert spaces: foundations and applications

CoQuS: Complex Quantum Systems

Cite this