Frontiers of quantum physics

Gravitationally-induced entanglement between two massive particles is sufficient evidence of quantum effects in gravity

(2017)

Authors:

Chiara Marletto, Vlatko Vedral

No-Hypersignaling Principle.

Physical review letters 119:2 (2017) 020401-020401

Authors:

Michele Dall'Arno, Sarah Brandsen, Alessandro Tosini, Francesco Buscemi, Vlatko Vedral

Abstract:

A paramount topic in quantum foundations, rooted in the study of the Einstein-Podolsky-Rosen (EPR) paradox and Bell inequalities, is that of characterizing quantum theory in terms of the spacelike correlations it allows. Here, we show that to focus only on spacelike correlations is not enough: we explicitly construct a toy model theory that, while not contradicting classical and quantum theories at the level of spacelike correlations, still displays an anomalous behavior in its timelike correlations. We call this anomaly, quantified in terms of a specific communication game, the "hypersignaling" phenomena. We hence conclude that the "principle of quantumness," if it exists, cannot be found in spacelike correlations alone: nontrivial constraints need to be imposed also on timelike correlations, in order to exclude hypersignaling theories.

Witness gravity's quantum side in the lab.

Nature Nature Research 547:7662 (2017) 156-158

Authors:

Chiara Marletto, Vlatko Vedral

Witness gravity's quantum side in the lab.

Nature 547:7662 (2017) 156-158

Authors:

Chiara Marletto, Vlatko Vedral

Device-Independent Tests of Quantum Measurements.

Physical review letters 118:25 (2017) 250501-250501

Authors:

Michele Dall'Arno, Sarah Brandsen, Francesco Buscemi, Vlatko Vedral

Abstract:

We consider the problem of characterizing the set of input-output correlations that can be generated by an arbitrarily given quantum measurement. Our main result is to provide a closed-form, full characterization of such a set for any qubit measurement, and to discuss its geometrical interpretation. As applications, we further specify our results to the cases of real and complex symmetric, informationally complete measurements and mutually unbiased bases of a qubit, in the presence of isotropic noise. Our results provide the optimal device-independent tests of quantum measurements.