News Release

Scientists make waves with black hole research

Peer-Reviewed Publication

University of Nottingham

Analogue Black Hole Machine

image: Analogue black hole machine is pictured. view more 

Credit: The University of Nottingham

Scientists at the University of Nottingham have made a significant leap forward in understanding the workings of one of the mysteries of the universe. They have successfully simulated the conditions around black holes using a specially designed water bath.

Their findings shed new light on the physics of black holes with the first laboratory evidence of the phenomenon known as the superradiance, achieved using water and a generator to create waves.

The research - Rotational superradiant scattering in a vortex flow - has been published in Nature Physics. It was undertaken by a team in the Quantum Gravity Laboratory in the School of Physics and Astronomy.

The work was led by Silke Weinfurtner from the School of Mathematical Sciences. In collaboration with an interdisciplinary team she designed and built the black hole 'bath' and measurement system to simulate black hole conditions.

Dr Weinfurtner said: "This research has been particularly exciting to work on as it has bought together the expertise of physicists, engineers and technicians to achieve our common aim of simulating the conditions of a black hole and proving that superadiance exists. We believe our results will motivate further research on the observation of superradiance in astrophysics."

What is superradiance?

The Nottingham experiment was based on the theory that an area immediately outside the event horizon of a rotating black hole - a black hole's gravitational point of no return - will be dragged round by the rotation and any wave that enters this region, but does not stray past the event horizon, should be deflected and come out with more energy than it carried on the way in - an effect known as superradiance.

Superadiance - the extraction of energy from a rotating black hole - is also known as the Penrose Mechanism and is a precursor of Hawking Radiation - a quantum version of black-hole superradiance.

What's in the Black Hole Lab?

Dr Weinfurtner said: "Some of the bizzare black hole phenomena are hard, if not, impossible to study directly. This means there are very limited experimental possibilities. So this research is quite an achievement."

The 'flume', is specially designed 3m long, 1.5m wide and 50cm deep bath with a hole in the centre. Water is pumped in a closed circuit to establish a rotating draining flow. Once at the desired depth waves were generated at varied frequenices until the supperadiant scattering effect is created and recorded using a specially designed 3D air fluid interface sensor.

Tiny dots of white paper punched out by a specially adapted sewing machine were used to measure the flow field - the speed of the fluid flow around the analogue black hole.

It all started from humble beginnings

This research has been many years in the making. The initial idea for creating a supperradiant effect with water started with a bucket and bidet. Dr Weinfurtner said: "This research has grown from humble beginnings. I had the initial idea for a water based experiment when I was at the International School for Advanced Studies (SISSA) in Italy and I set up an experiment with a bucket and a bidet. However, when it caused a flood I was quickly found a lab to work in!

After her postdoc, Dr Weinfurtner went on to work with Bill Unruh, the Canadian born physicist who also has a made seminal contributions to our understanding of gravity, black holes, cosmology, quantum fields in curved spaces, and the foundations of quantum mechanics, including the discovery of the Unruh effect.

Her move to the University of Nottingham accelerated her research as she was able to set up her own research group with support from the machine shop in the School of Physics and Astronomy.

###

This research is funded by the Engineering and Physical Sciences Research Council, the Royal Society and the University of Nottingham.

High res images are available. If used please credit the University of Nottingham.


Disclaimer: AAAS and EurekAlert! are not responsible for the accuracy of news releases posted to EurekAlert! by contributing institutions or for the use of any information through the EurekAlert system.