Backreaction in an analogue black hole experiment

For many physical systems of interest, there is a natural division between a quasi-stationary background and small perturbations on that background. In curved spacetime scenarios the perturbations can either be of classical or quantum origin, and much progress has been made in understanding the behaviour of such perturbations by assuming a fixed background. Less understood is how these perturbations in turn alter the background structure - a phenomenon known as backreaction. In this letter we report on the first measurement of backreaction in an analogue gravity simulator. We scatter surface waves from a draining bathtub vortex, in analogy with scalar waves scattering from a rotating black hole. We predict and detect a mass flux associated with the surface waves that flows through the analogue event horizon and out the drain. This manifests itself in a measurable decrease in the water height that agrees with our theoretical prediction. Changes in water height correspond to changes in the effective gravitational field, as energy and angular momentum are exchanged between the incident waves and the analogue black hole. Although our experimental findings are constrained to classical systems, our conceptual framework can be generalized to apply to quantum systems. Hence, we argue that analogue quantum simulators of gravitational systems could be used to investigate black hole backreaction due to the processes predicted by Penrose and Hawking.