Energy-Time Uncertainty Relations in Quantum Measurements

Foundations of Physics 46 (11):1522-1550 (2016)
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Abstract

Quantum measurement is a physical process. A system and an apparatus interact for a certain time period, and during this interaction, information about an observable is transferred from the system to the apparatus. In this study, we quantify the energy fluctuation of the quantum apparatus required for this physical process to occur autonomously. We first examine the so-called standard model of measurement, which is free from any non-trivial energy–time uncertainty relation, to find that it needs an external system that switches on the interaction between the system and the apparatus. In such a sense this model is not closed. Therefore to treat a measurement process in a fully quantum manner we need to consider a “larger” quantum apparatus which works also as a timing device switching on the interaction. In this setting we prove that a trade-off relation, \, holds between the energy fluctuation \ of the quantum apparatus and the measurement time \. We use this trade-off relation to discuss the spacetime uncertainty relation concerning the operational meaning of the microscopic structure of spacetime. In addition, we derive another trade-off inequality between the measurement time and the strength of interaction between the system and the apparatus.

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10.1007/s10701-016-0027-6

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Citations of this work

Relative Quantum Time.Leon Loveridge & Takayuki Miyadera - 2019 - Foundations of Physics 49 (6):549-560.

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References found in this work

Quantum Theory and Measurement.J. A. Wheeler & W. H. Zurek - 1986 - Synthese 67 (3):527-530.
La Nouvelle Cuisine.J. S. Bell - 1987 - In John Stewart Bell (ed.), Speakable and unspeakable in quantum mechanics: collected papers on quantum philosophy. New York: Cambridge University Press. pp. 232--248.

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