Quantum clocks observe classical and quantum time dilation

Smith, Alexander R. H.; Ahmadi, Mehdi

doi:10.1038/s41467-020-18264-4

Cited by 87 publications

(89 citation statements)

References 64 publications

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“…While a Newton-Wigner type localization is approximate and not fully Lorentz covariant, due to the relativistic localization nogo theorems of Perez-Wilde [92] and Malament [93] (see also [94,95]), it is generally accepted as the best possible localization in relativistic quantum mechanics (In quantum field theory localization is a different matter [90,94]). This demonstrates the advantage of using covariant clock POVMs in relational quantum dynamics [7,44,45,96,97]. The trinity also extends the probabilistic interpretation of relational observables: a Dirac observable describing the relation between a position operator and the covariant clock POVM corresponds to a Newton-Wigner type localization in relativistic settings.…”

Section: Introductionmentioning

confidence: 81%

“…In the second line we made use of Equation (45), in the third of Theorem 1, and in the fourth of Equation ( 71) and the fact that θ (−σ 1p1 ) commutes with the reduction map of the C 2 clock and withF O C 2 S|C 1 ,T 1 (τ 1 ) (see Lemma 5).…”

Section: Observable Transformations In the Relational Schrödinger Picturementioning

confidence: 99%

“…(i) a Dirac quantization scheme, wherein relational observables are constructed that encode correlations between evolving and clock degrees of freedom [1,2,4,, (ii) the Page-Wootters formalism, which defines a relational dynamics in terms of conditional probabilities for clock and evolving degrees of freedom [7,25,[39][40][41][42][43][44][45][46][47][48][49][50][51][52][53][54][55][56][57], and (iii) classical or quantum deparametrizations, which result in a reduced quantum theory that only treats the evolving degrees of freedom as quantum [1,2,7,10,30,31,[58][59][60][61][62][63][64][65].…”

Section: Introductionmentioning

confidence: 99%

“…This degeneracy is not covered by our previous construction. While quadratic clock Hamiltonians are standard in the literature on relational observables [approach (i)] and deparametrizations [approach (iii)], see e.g., [4,10,11,19,29,31], relativistic particle models have only recently been studied in the Page-Wootters formalism [approach (ii)] [45,[49][50][51]. However, Kuchař's criticism (a) that the Page-Wootters approach yields incorrect localization probabilities in relativistic settings has yet to be addressed.…”

Section: Introductionmentioning

confidence: 99%

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Equivalence of Approaches to Relational Quantum Dynamics in Relativistic Settings

2021

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We have previously shown that three approaches to relational quantum dynamics—relational Dirac observables, the Page-Wootters formalism and quantum deparametrizations—are equivalent. Here we show that this “trinity” of relational quantum dynamics holds in relativistic settings per frequency superselection sector. Time according to a clock subsystem is defined via a positive operator-valued measure (POVM) that is covariant with respect to the group generated by its (quadratic) Hamiltonian. This differs from the usual choice of a self-adjoint clock observable conjugate to the clock momentum. It also resolves Kuchař's criticism that the Page-Wootters formalism yields incorrect localization probabilities for the relativistic particle when conditioning on a Minkowski time operator. We show that conditioning instead on the covariant clock POVM results in a Newton-Wigner type localization probability commonly used in relativistic quantum mechanics. By establishing the equivalence mentioned above, we also assign a consistent conditional-probability interpretation to relational observables and deparametrizations. Finally, we expand a recent method of changing temporal reference frames, and show how to transform states and observables frequency-sector-wise. We use this method to discuss an indirect clock self-reference effect and explore the state and temporal frame-dependence of the task of comparing and synchronizing different quantum clocks.

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Section: Introductionmentioning

confidence: 81%

Section: Observable Transformations In the Relational Schrödinger Picturementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Equivalence of Approaches to Relational Quantum Dynamics in Relativistic Settings

2021

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“…Perhaps a PaW formulation of spacetime may represent a first step towards removing this asymmetry. This might help to develop relativistic generalizations of the PaW formalism, see also [31,32,33,34].…”

Section: Discussionmentioning

confidence: 99%

Time Observables in a Timeless Universe

Favalli

Smerzi

2020

Quantum

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Time in quantum mechanics is peculiar: it is an observable that cannot be associated to an Hermitian operator. As a consequence it is impossible to explain dynamics in an isolated system without invoking an external classical clock, a fact that becomes particularly problematic in the context of quantum gravity. An unconventional solution was pioneered by Page and Wootters (PaW) in 1983. PaW showed that dynamics can be an emergent property of the entanglement between two subsystems of a static Universe. In this work we first investigate the possibility to introduce in this framework a Hermitian time operator complement of a clock Hamiltonian having an equally-spaced energy spectrum. An Hermitian operator complement of such Hamiltonian was introduced by Pegg in 1998, who named it "Age". We show here that Age, when introduced in the PaW context, can be interpreted as a proper Hermitian time operator conjugate to a "good" clock Hamiltonian. We therefore show that, still following Pegg's formalism, it is possible to introduce in the PaW framework bounded clock Hamiltonians with an unequally-spaced energy spectrum with rational energy ratios. In this case time is described by a POVM and we demonstrate that Pegg's POVM states provide a consistent dynamical evolution of the system even if they are not orthogonal, and therefore partially undistinguishables.

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Gravitational Redshift Induces Quantum Interference

Bruschi

Schell

2022

Annalen der Physik

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Quantum field theory in curved spacetime is used to show that gravitational redshift induces a unitary transformation on the quantum state of propagating photons. It is found that the transformation is a mode-mixing operation, and a protocol that exploits gravity to induce a Hong-Ou-Mandel-like interference effect on the state of two photons is devised. It is discussed how the results of this work can provide a demonstration of quantum field theory in curved spacetime.

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Quantum clocks observe classical and quantum time dilation

Cited by 87 publications

References 64 publications

Equivalence of Approaches to Relational Quantum Dynamics in Relativistic Settings

Equivalence of Approaches to Relational Quantum Dynamics in Relativistic Settings

Time Observables in a Timeless Universe

Gravitational Redshift Induces Quantum Interference

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