Abstract
We propose an experiment combining fluid dynamics and strong magnetic field physics to simulate cosmological scenarios. Our proposed system consists of two immiscible, weakly magnetized fluids moved through a strong gradient magnetic field. The diamagnetic and paramagnetic forces thus generated amount to a time-dependent effective gravity, which allows us to precisely control the propagation speed of interface waves. Perturbations on the interface therefore experience a nonstationary effective metric. In what follows, we demonstrate that our proposed system is capable of simulating a variety of cosmological models. We then present a readily realizable experimental setup which will allow us to capture the essential dynamics of standard inflation, wherein interface perturbations experience a shrinking effective horizon and are shown to transition from oscillatory to frozen and squeezed regimes at horizon crossing.
Highlights
We propose a novel experiment combining fluid dynamics and strong magnetic field physics to simulate cosmological scenarios
We present a readily realisable experimental setup which will allow us to capture the essential dynamics of standard inflation, wherein interface perturbations experience a shrinking effective horizon and are shown to transition from oscillatory to frozen and squeezed regimes at horizon crossing
The physics of the early universe is deeply linked to drastic changes in spacetime geometry
Summary
We propose a novel experiment combining fluid dynamics and strong magnetic field physics to simulate cosmological scenarios. The diamagnetic and paramagnetic forces generated amount to a time-dependent effective gravity, which allows us to precisely control the propagation speed of interface waves.
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