Gravitationally-induced entanglement in cold atoms
- URL: http://arxiv.org/abs/2304.00734v2
- Date: Tue, 8 Aug 2023 09:10:10 GMT
- Title: Gravitationally-induced entanglement in cold atoms
- Authors: Richard Howl, Nathan Cooper, Lucia Hackerm\"uller
- Abstract summary: gravitationally-induced entanglement (GIE) between two or more quantum matter systems is a promising route to testing quantum gravity.
Here, we consider, for the first time, GIE between two atomic gas interferometers as a test of quantum gravity.
We propose placing the two interferometers next to each other in parallel and looking for correlations in the number of atoms at the output ports as evidence of GIE and quantum gravity.
- Score: 3.8029070240258687
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: A promising route to testing quantum gravity in the laboratory is to look for
gravitationally-induced entanglement (GIE) between two or more quantum matter
systems. Proposals for such tests have principally used microsolid systems,
with highly non-classical states, such as N00N states or highly-squeezed
states. Here, we consider, for the first time, GIE between two atomic gas
interferometers as a test of quantum gravity. We propose placing the two
interferometers next to each other in parallel and looking for correlations in
the number of atoms at the output ports as evidence of GIE and quantum gravity.
GIE is possible without challenging macroscopic superposition states, such as
N00N or Schr\"odinger cat states, and instead there can be just classical-like
'coherent' states of atoms. This requires the total mass of the atom
interferometers to be on the Planck mass scale, and long integration times.
However, with current state-of-the-art quantum squeezing in cold atoms, we
argue that the mass scale can be reduced to approachable levels and detail how
such a mass scale can be achieved in the near future.
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