Quantum Information Processing and Relativistic Quantum Fields
Abstract
It is shown that an ideal measurement of a one-particle wave packet state of a relativistic quantum field in Minkowski spacetime enables superluminal signalling. The result holds for a measurement that takes place over an intervention region in spacetime whose extent in time in some frame is longer than the light-crossing time of the packet in that frame. Moreover, these results are shown to apply not only to ideal measurements but also to unitary transformations that rotate two orthogonal one-particle states into each other. In light of these observations, possible restrictions on the allowed types of intervention are considered. A more physical approach to such questions is to construct explicit models of the interventions as interactions between the field and other quantum systems such as detectors. The prototypical Unruh-DeWitt detector couples to the field operator itself and so most likely respects relativistic causality. On the other hand, detector models which couple to a finite set of frequencies of field modes are shown to lead to superluminal signalling. Such detectors do, however, provide successful phenomenological models of atom-qubits interacting with quantum fields in a cavity but are valid only on time scales many orders of magnitude larger than the light-crossing time of the cavity.
Cite
@article{arxiv.1206.5205,
title = {Quantum Information Processing and Relativistic Quantum Fields},
author = {Dionigi M. T. Benincasa and Leron Borsten and Michel Buck and Fay Dowker},
journal= {arXiv preprint arXiv:1206.5205},
year = {2014}
}
Comments
16 pages, 2 figures. Improved abstract and discussion of 'ideal' measurements. References to previous work added