Your search keyword '"Gasbarri G"' showing total 4 results

1. Gravitational decoherence: A nonrelativistic spin 1/2 fermionic model.

Author

Asprea, L. and Gasbarri, G.

Subjects

*GRAVITATIONAL fields, *ELECTROMAGNETIC fields, *PARTICLE spin, *FERMIONS, *NONRELATIVISTIC quantum mechanics

Abstract

In a previous work [L. Asprea, G. Gasbarri, and A. Bassi, Gravitational decoherence: A general nonrelativistic model, Phys. Rev. D 103, 104041 (2021).] we derived a quantum master equation for the dynamics of a scalar bosonic particle interacting with a weak, stochastic and classical gravitational field. As standard matter is made of fermions, such an equation should be suitably extended to describe more relevant experimental situations. Here we derive a nonrelativistic model for the gravitational decoherence of spin 1/2 particles. We enrich the treatment by also considering a coupling with an external classical electromagnetic field. We comment on the differences with the scalar bosonic model and we describe the regimes in which they become negligible. [ABSTRACT FROM AUTHOR]

Published

2021

2. Gravitational decoherence: A general nonrelativistic model.

Author

Asprea, L., Gasbarri, G., and Bassi, A.

Subjects

*GRAVITATIONAL fields

Abstract

We derive a general quantum master equation for the dynamics of a scalar bosonic particle interacting with a weak, stochastic and classical external gravitational field. The dynamics predicts decoherence in position, momentum and energy. We show how our master equation reproduces the results present in the literature by taking appropriate limits, thus explaining the apparent contradiction in their dynamical description. Our result is relevant in light of the increasing interest in the low energy quantum-gravity regime. [ABSTRACT FROM AUTHOR]

Published

2021

3. Gravity induced wave function collapse.

Author

Gasbarri, G., Toroš, M., Donadi, S., and Bassi, A.

Subjects

*QUANTUM gravity, *WAVE functions, *GRAVITATIONAL waves

Abstract

Starting from an idea of S. L. Adler [in Quantum Nonlocality and Reality: 50 Years of Bell's Theorem, edited by M. Bell and S. Gao (Cambridge University Press, Cambridge, England 2016)], we develop a novel model of gravity induced spontaneous wave function collapse. The collapse is driven by complex stochastic fluctuations of the spacetime metric. After deriving the fundamental equations, we prove the collapse and amplification mechanism, the two most important features of a consistent collapse model. Under reasonable simplifying assumptions, we constrain the strength ξ of the complex metric fluctuations with available experimental data. We show that ξ≥10-26 in order for the model to guarantee classicality of macro-objects, and at the same time ξ≤10-20 in order not to contradict experimental evidence. As a comparison, in the recent discovery of gravitational waves in the frequency range 35 to 250 Hz, the (real) metric fluctuations reach a peak of ξ~10-21. [ABSTRACT FROM AUTHOR]

Published

2017

4. Test quantum mechanics in space - invest US$1 billion.

Author

Belenchia A, Carlesso M, Donadi S, Gasbarri G, Ulbricht H, Bassi A, and Paternostro M

Published

2021