New Journal of Physics (Jan 2014)
Experimental quantum cosmology in time-dependent optical media
Abstract
It is possible to construct artificial spacetime geometries for light by using intense laser pulses that modify the spatiotemporal properties of an optical medium. Here we theoretically investigate experimental possibilities for studying spacetime metrics of the form ${\rm d}{{s}^{2}}={{c}^{2}}{\rm d}{{t}^{2}}-\eta {{\left( t \right)}^{2}}{\rm d}{{x}^{2}}$ . By tailoring the laser pulse shape and medium properties, it is possible to create a refractive index variation $n=n\left( t \right)$ that can be identified with $\eta \left( t \right)$ . Starting from a perturbative solution to a generalized Hopfield model for the medium described by an $n=n\left( t \right)$ , we provide estimates for the number of photons generated by the time-dependent spacetime. The simplest example is that of a uniformly varying $\eta \left( t \right)$ that therefore describes the Robertson–Walker metric, i.e. a cosmological expansion. The number of photon pairs generated in experimentally feasible conditions appears to be extremely small. However, large photon production can be obtained by periodically modulating the medium and thus resorting to a resonant enhancement similar to that observed in the dynamical Casimir effect. Curiously, the spacetime metric in this case closely resembles that of a gravitational wave. Motivated by this analogy, we show that a periodic gravitational wave can indeed act as an amplifier for photons. The emission for an actual gravitational wave will be very weak but should be readily observable in the laboratory analogue.
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