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Quantum time dilation in atomic spectra

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

2021Physical Review Research18 citationsDOIOpen Access PDF

Abstract

Quantum time dilation occurs when a clock moves in a superposition of relativistic momentum wave packets. The lifetime of an excited hydrogenlike atom can be used as a clock, which we use to demonstrate how quantum time dilation manifests in a spontaneous emission process. The resulting emission rate differs when compared with the emission rate of an atom prepared in a mixture of momentum wave packets at order v 2 /c 2 . This effect is accompanied by a quantum correction to the Doppler shift due to the coherence between momentum wave packets. This quantum Doppler shift affects the spectral line shape at order v/c. However, its effect on the decay rate is suppressed when compared with the effect of quantum time dilation. We argue that spectroscopic experiments offer a technologically feasible platform to explore the effects of quantum time dilation.

Topics & Concepts

PhysicsExcited stateQuantumWave packetTime dilationSuperposition principleSpectral lineCoherence (philosophical gambling strategy)Principal quantum numberDoppler effectAtom (system on chip)Atomic physicsSpontaneous emissionQuantum mechanicsMomentum (technical analysis)Quantum superpositionEmission spectrumQuantum systemCoherence timeQuantum beatsQuantum dissipationQuantum dynamicsLaserUltracold atomTime evolutionAzimuthal quantum numberTotal angular momentum quantum numberAngular momentumQuantum opticsDoppler broadeningQuantum optics and atomic interactionsQuantum Mechanics and ApplicationsQuantum chaos and dynamical systems
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