Quantum conformal symmetries for spacetimes in superposition

Kabel, Viktoria; Hamette, Anne-Catherine de la; Castro-Ruiz, Esteban; Brukner, Časlav

doi:10.48550/arxiv.2207.00021

Cited by 2 publications

(2 citation statements)

References 31 publications

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“…Moreover, it contributes to a growing body of recent results that demonstrate the close connection of QRFs to gravitational physics, and boundary modes, e.g. [12,13,56,58,[60][61][62]. In particular, QRF transformations that realize global translations and rotations [58] and local coordinate transformations [56,57] have been developed and applied to gravitational physics.…”

Section: Outlook and Discussionmentioning

confidence: 96%

Quantum Reference Frames at the Boundary of Spacetime

Kabel¹,

Brukner²,

Wieland³

2023

Preprint

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An analysis is given of the local phase space of gravity coupled to matter to second order in perturbation theory. Working in local regions with boundaries at finite distance, we identify matter, Coulomb, and additional boundary modes. The boundary modes take the role of reference frames for both diffeomorphisms and internal Lorentz rotations. Passing to the quantum level, we identify the constraints that link the bulk and boundary modes. The constraints take the form of a multifingered Schrödinger equation, which determines the relational evolution of the quantum states in the bulk with respect to the quantum reference fields at the boundary. Contents

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Section: Outlook and Discussionmentioning

confidence: 96%

Quantum Reference Frames at the Boundary of Spacetime

Kabel¹,

Brukner²,

Wieland³

2023

Preprint

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“…One common postulate in physics is the assumption that the existence of an ideal clock, which is capable of measuring proper time precisely. possible to generalize this principle to scenarios, when inertial observers follow a superposition of paths [41][42][43].…”

Section: Introductionmentioning

confidence: 99%

Universality of quantum time dilation

Dębski,

Grochowski,

Demkowicz-Dobrzański

et al. 2024

Class. Quantum Grav.

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Time dilation is a difference in measured time between two clocks that either move with different velocities or experience different gravitational potentials. Both of these effects stem from the theory of relativity and are usually associated with classically defined trajectories, characterized by position, momentum, and acceleration. However, when spatial degrees of freedom are treated in a quantum way and a clock is allowed to be in a coherent superposition of either two momenta or two heights, additional quantum corrections to classical time dilation appear, called kinematic and gravitational quantum time dilations, respectively. We show that similarly to its classical counterpart, kinematic quantum time dilation is universal for any clock mechanism, while gravitationalquantum time dilation is not. We also show that although both of these effects reduce to incoherent averaging of different classical time dilation contributions, there exists an additional quantum time dilation effect that has no classical analog and can be extracted from higher-order corrections to the system’s Hamiltonian.

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Quantum conformal symmetries for spacetimes in superposition

Cited by 2 publications

References 31 publications

Quantum Reference Frames at the Boundary of Spacetime

Quantum Reference Frames at the Boundary of Spacetime

Universality of quantum time dilation

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