Reaction was first observed in simulations of the black hole in the water tank

Scientists have revealed new insights into the behavior of black holes with research demonstrating how a phenomenon called backlash can be simulated.

The University of Nottingham team used their simulation of a black hole with a specially designed water tank for this latest research conducted in Physical overview letters. This study is the first to show that the evolution of black holes due to the surrounding fields can be simulated in a laboratory experiment.

The researchers use a water tank simulator that consists of a draining vortex, like the shape when you pull the plug into the bath. It mimics a black hole, as a wave that gets too close to the drain is dragged through the plug hole and cannot escape. Systems like these have become increasingly popular over the past decade as a way to test gravitational phenomena in a controlled laboratory environment. In particular, Hawking radiation was observed in an analog black hole experiment with quantum optics.

Using this technique, the researchers showed for the first time that when the waves are sent to an analog black hole, the properties of the black hole itself can change significantly. The mechanism underlying this effect in their particular experiment has a remarkably simple explanation. When waves get close to the drain, it effectively pushes more water into the plug hole, so that the total amount of water in the tank decreases. This results in a change in water level, which in the simulation corresponds to a change in the properties of the black hole.

Lead author, postdoctoral researcher dr. Sam Patrick of the University of Nottingham School of Mathematical Sciences explains: ‘It has long been unclear whether the backlash would lead to measurable changes in analog systems where the fluid flow is powered, for example, using a water pump. We have shown that analog black holes, like their counterparts for gravity, are intrinsic reaction systems. We have shown that waves traveling in a run-off bath push water through the plug hole, which significantly changes the drain speed and consequently changes the effective gravity pull of the analog black hole.

What was striking to us was that the back reaction is large enough so that it lowers the water level over the entire system so that you can see it with the naked eye! It was really unexpected. Our study paves the way for experimentally investigating interactions between waves and the space times in which they move. This type of interaction would be crucial, for example, for the investigation of evaporation of black holes in the laboratory. ‘

Black Hole Research at the University of Nottingham recently received a £ 4.3 million boost for a three-year project aimed at providing further insights into the physics of the early universe and black holes.

The research team will use quantum simulators to mimic the extreme conditions of the early universe and black holes. The Nottingham team will use a new state laboratory to set up a new hybrid superfluid optomechanical system to mimic quantum processes in the laboratory.