Quantum time dilation in atomic spectra

Piotr T. Grochowski; Alexander R. H. Smith; Andrzej Dragan; Kacper Dębski

doi:10.1103/physrevresearch.3.023053

Quantum clocks observe classical and quantum time dilation

Nature Communications ◽

10.1038/s41467-020-18264-4 ◽

2020 ◽

Vol 11 (1) ◽

Cited By ~ 2

Author(s):

Alexander R. H. Smith ◽

Mehdi Ahmadi

Keyword(s):

Uncertainty Relation ◽

Proper Time ◽

Wave Packets ◽

Center Of Mass ◽

Time Dilation ◽

Conditional Probability Distribution ◽

Quantum Time ◽

Mass Uncertainty ◽

Quantum Clocks ◽

Relativistic Particles

Abstract At the intersection of quantum theory and relativity lies the possibility of a clock experiencing a superposition of proper times. We consider quantum clocks constructed from the internal degrees of relativistic particles that move through curved spacetime. The probability that one clock reads a given proper time conditioned on another clock reading a different proper time is derived. From this conditional probability distribution, it is shown that when the center-of-mass of these clocks move in localized momentum wave packets they observe classical time dilation. We then illustrate a quantum correction to the time dilation observed by a clock moving in a superposition of localized momentum wave packets that has the potential to be observed in experiment. The Helstrom-Holevo lower bound is used to derive a proper time-energy/mass uncertainty relation.

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Do Atomic Spectra Determine Energy Levels?

Journal de Physique I ◽

10.1051/jp1:1995175 ◽

1995 ◽

Vol 5 (8) ◽

pp. 949-961 ◽

Cited By ~ 2

Author(s):

C. Billionnet

Keyword(s):

Energy Levels ◽

Atomic Spectra

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REVIEW OF ELECTRIC AND MAGNETIC CONFIGURATION-MIXING EFFECTS IN ATOMIC SPECTRA

Le Journal de Physique Colloques ◽

10.1051/jphyscol:1982201 ◽

1982 ◽

Vol 43 (C2) ◽

pp. C2-1-C2-12 ◽

Cited By ~ 1

Author(s):

W. R.S. Garton

Keyword(s):

Magnetic Configuration ◽

Atomic Spectra ◽

Mixing Effects ◽

Configuration Mixing

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Rydberg and the development of atomic spectroscopy (Centennial of J. R. Rydberg's paper on the laws governing atomic spectra)

Uspekhi Fizicheskih Nauk ◽

10.3367/ufnr.0160.199012f.0141 ◽

1990 ◽

Vol 160 (12) ◽

pp. 141

Author(s):

M.A. El'yashevich ◽

N.G. Kembrovskaya ◽

L.M. Tomil'chik

Keyword(s):

Atomic Spectroscopy ◽

Atomic Spectra

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Simulation of Quantum Time-Frequency Transform Algorithms

10.21236/ada435027 ◽

2005 ◽

Author(s):

Chao Lu

Keyword(s):

Time Frequency ◽

Quantum Time

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Quantum Becoming?

10.1093/oso/9780198797302.003.0004 ◽

2017 ◽

Author(s):

Craig Callender

Keyword(s):

Quantum Mechanics ◽

Quantum Theory ◽

Quantum Time ◽

Quantum Non Locality ◽

Time Quantum ◽

Temporal Becoming ◽

Non Locality ◽

Quantum Wavefunction

Two of quantum mechanics’ more famed and spooky features have been invoked in defending the idea that quantum time is congenial to manifest time. Quantum non-locality is said by some to make a preferred foliation of spacetime necessary, and the collapse of the quantum wavefunction is held to vindicate temporal becoming. Although many philosophers and physicists seek relief from relativity’s assault on time in quantum theory, assistance is not so easily found.

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Quantum simulations

10.1093/oso/9780198803195.003.0013 ◽

2017 ◽

Author(s):

Michael P. Allen ◽

Dominic J. Tildesley

Keyword(s):

Ab Initio ◽

Quantum Monte Carlo ◽

Degrees Of Freedom ◽

Small Region ◽

Time Correlation ◽

Ab Initio Molecular Dynamics ◽

Classical Dynamics ◽

Integral Methods ◽

Quantum Time ◽

Low Mass

This chapter covers the introduction of quantum mechanics into computer simulation methods. The chapter begins by explaining how electronic degrees of freedom may be handled in an ab initio fashion and how the resulting forces are included in the classical dynamics of the nuclei. The technique for combining the ab initio molecular dynamics of a small region, with classical dynamics or molecular mechanics applied to the surrounding environment, is explained. There is a section on handling quantum degrees of freedom, such as low-mass nuclei, by discretized path integral methods, complete with practical code examples. The problem of calculating quantum time correlation functions is addressed. Ground-state quantum Monte Carlo methods are explained, and the chapter concludes with a forward look to the future development of such techniques particularly to systems that include excited electronic states.

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The Equivalence Principle

10.1093/oso/9780199658633.003.0013 ◽

2018 ◽

Author(s):

David M. Wittman

Keyword(s):

General Relativity ◽

Special Relativity ◽

Equivalence Principle ◽

Time Dilation ◽

Gravitational Redshift ◽

Coordinate Systems ◽

Spacetime Metric

The equivalence principle is an important thinking tool to bootstrap our thinking from the inertial coordinate systems of special relativity to the more complex coordinate systems that must be used in the presence of gravity (general relativity). The equivalence principle posits that at a given event gravity accelerates everything equally, so gravity is equivalent to an accelerating coordinate system.This conjecture is well supported by precise experiments, so we explore the consequences in depth: gravity curves the trajectory of light as it does other projectiles; the effects of gravity disappear in a freely falling laboratory; and gravitymakes time runmore slowly in the basement than in the attic—a gravitational form of time dilation. We show how this is observable via gravitational redshift. Subsequent chapters will build on this to show how the spacetime metric varies with location.

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Energy and Momentum

10.1093/oso/9780199658633.003.0012 ◽

2018 ◽

Author(s):

David M. Wittman

Keyword(s):

Time Dilation ◽

Speed Of Light ◽

Massless Particles ◽

The Everyday ◽

Low Speeds ◽

Energy And Momentum ◽

Deep Relationship ◽

Insight Into ◽

Momentum Relation

Tis chapter explains the famous equation E = mc2 as part of a wider relationship between energy, mass, and momentum. We start by defning energy and momentum in the everyday sense. We then build on the stretching‐triangle picture of spacetime vectors developed in Chapter 11 to see how energy, mass, and momentum have a deep relationship that is not obvious at everyday low speeds. When momentum is zero (a mass is at rest) this energy‐momentum relation simplifes to E = mc2, which implies that mass at rest quietly stores tremendous amounts of energy. Te energymomentum relation also implies that traveling near the speed of light (e.g., to take advantage of time dilation for interstellar journeys) will require tremendous amounts of energy. Finally, we look at the simplifed form of the energy‐momentum relation when the mass is zero. Tis gives us insight into the behavior of massless particles such as the photon.

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Practical Security of RSA Against NTC-Architecture Quantum Computing Attacks

International Journal of Theoretical Physics ◽

10.1007/s10773-021-04789-x ◽

2021 ◽

Author(s):

Kai Li ◽

Qing-yu Cai

Keyword(s):

Quantum Computing ◽

Ion Trap ◽

Quantum Algorithms ◽

Coherence Time ◽

Quantum Computers ◽

Quantum Time ◽

Speed Up ◽

Key Length ◽

Concurrent Architecture ◽

Qubit Gate

AbstractQuantum algorithms can greatly speed up computation in solving some classical problems, while the computational power of quantum computers should also be restricted by laws of physics. Due to quantum time-energy uncertainty relation, there is a lower limit of the evolution time for a given quantum operation, and therefore the time complexity must be considered when the number of serial quantum operations is particularly large. When the key length is about at the level of KB (encryption and decryption can be completed in a few minutes by using standard programs), it will take at least 50-100 years for NTC (Neighbor-only, Two-qubit gate, Concurrent) architecture ion-trap quantum computers to execute Shor’s algorithm. For NTC architecture superconducting quantum computers with a code distance 27 for error-correcting, when the key length increased to 16 KB, the cracking time will also increase to 100 years that far exceeds the coherence time. This shows the robustness of the updated RSA against practical quantum computing attacks.

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