Abstract
The recent experimental proposals by Bose et al. and Marletto et al. (BMV) outline a way to test for the quantum nature of gravity by measuring gravitationally induced differential phase accumulation over the superposed paths of two ∼ 10−14 kg masses. These authors outline the expected outcome of these experiments for semi-classical, quantum gravity and collapse models. It is found that both semi-classical and collapse models predict a lack of entanglement in the experimental results. This work predicts the outcome of the BMV experiment in Bohmian trajectory gravity - where classical gravity is assumed to couple to the particle configuration in each Bohmian path, as opposed to semi-classical gravity where gravity couples to the expectation value of the wave function, or of quantized gravity, where the gravitational field is itself in a quantum superposition. In the case of the BMV experiment, Bohmian trajectory gravity predicts that there will be quantum entanglement. This is surprising as the gravitational field is treated classically. A discussion of how Bohmian trajectory gravity can induce quantum entanglement for a non superposed gravitational field is put forward.
Highlights
In papers published in 2017, Bose et al.[1], and Marleto and Vedral[2] (BMV) describe an experimental proposal to test for quantum gravity
There are collapse models where particles as massive as that used in the proposed BMV experiment will collapse the wave function.[8]
The result prediction for Bohmian trajectory gravity shows entanglement with a witness of
Summary
In papers published in 2017, Bose et al.[1], and Marleto and Vedral[2] (BMV) describe an experimental proposal to test for quantum gravity. In some cases such as semi-classical and quantized gravity case the final state is pure, while in others a mixed state is the result. In semi-classical gravity the gravitational field of a particle in a quantum state is taken to be the expectation value of the position of the particle.
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