Southampton Set to Support Development of Next-gen Gravitational Wave Detectors – Technology Org

University of Southampton researchers are set to play a key role in developing the next generation of gravitational wave detectors, which could help astronomers probe the furthest reaches of the cosmos.

Southampton Set to Support Development of Next-gen Gravitational Wave Detectors – Technology Org

Space – illustrative photo. Image credit: Pixabay (Free Pixabay license)

A consortium of seven British universities, including the University of Southampton, has secured £7m in support from the UK Research and Innovation (UKRI) Infrastructure Fund.

The project brings together gravity experts from the universities of Birmingham, Cardiff, Glasgow, Portsmouth, Southampton, Strathclyde and the West of Scotland. Over the next three years, they will develop designs for new mirror coatings, data analysis techniques, and suspension and seismic isolation systems for use in two future international gravitational wave detector development projects.

The projects – Cosmic Explorer in the United States and the Einstein Telescope in Europe – are currently in the early stages of design work. They are expected to be fully constructed and online by the end of the next decade.

The international collaborations behind the next-gen detectors expect they will be sensitive enough to detect signals from the very edge of the universe.

What are gravitational waves?

Gravitational waves are faint ripples in spacetime caused by enormous astronomical events like the collision of black holes.

Gravitational wave detectors work by bouncing lasers between mirrors suspended at each end of long pipes often arranged in an L-shape. As the waves pass through the detectors, they cause miniscule variations in the distance between the mirrors measured by the lasers.

Analysis of the data captured during the passthrough of the gravitational waves can reveal a wealth of information about their origins in space.

The LIGO observatory made the historic first detection of gravitational waves in 2015, opening up an entirely new field of astronomy which ‘listens’ for vibrations in spacetime, instead of looking for information from across the electromagnetic spectrum. Since then, gravitational wave detectors have made spectacular discoveries – including signals from more than 100 pairs of colliding black holes.

Next generation detectors

The next generation of detectors will be significantly more ambitious than current designs, with lasers bounced between mirrors suspended free of external vibration placed up to 40km apart instead of 4km. The mirrors, too, will be bigger and heavier as they double in diameter to around 60cm.

The expanded reach of the detectors will help cast new light on how black holes were formed in the earliest epochs of time, how matter behaves in neutron stars, and pick up gravitational waves which current observatories are unable to detect.

Professor Nils Andersson, co-investigator on the project and Head of the University of Southampton Gravity group said: “I am very excited about this project. It is an important step towards the development of incredibly sensitive gravitational-wave observatories that will allow us to explore the dark side of the Universe at a level of detail we can only imagine today. We will learn so much more about black holes and the extreme physics of neutron stars. This promises to be a fascinating journey.”

Scientists from the UK, funded by the Science and Technology Facilities Council (STFC), have been involved in gravitational wave research for several decades. They contributed to the design, mirror suspension technology and data analysis which underpins the current generation of gravitational wave observatories – LIGO in the United States, Virgo in Italy, and KAGRA in Japan.

‘Hundreds of detections a year, to hundreds of thousands’

Professor Sheila Rowan, Director of the University of Glasgow’s Institute for Gravitational Research and lead investigator on the project, said: “I’m excited to be continuing our work with the STFC and partners across the UK to develop key components of the next generation of gravitational wave observatories, which have the potential to revolutionise our understanding of the universe.

“We’ve learned a vast amount from LIGO, Virgo and KAGRA already, and we’re currently partway through our fourth major observing run which is bringing us, on average, several new detections a week. The next-generation could deliver a leap from hundreds of detections a year to hundreds of thousands – a vast treasure trove of new information which brings with it new challenges in processing the data which we’ll be working to help solve in the years to come.

Professor Mark Thomson, Executive Chair of the Science and Technology Facilities Council (STFC) and UK Research and Innovation (UKRI) Champion for Infrastructure, said: “The detection of gravitational waves has been one of the most exciting recent developments in science and has provided us with entirely new way of observing the universe.

“This new UKRI investment will enable UK scientists to play a key role in the international effort to develop the next generation of even more sensitive gravitational wave observatories, which will greatly expand our understanding of the cosmos.”

“The UK has been a key contributor to Initial and Advanced LIGO, and currently the A+ upgrade in the US, and the continued participation of our UK colleagues gives us confidence that our scientific goals can be realized,” said David Shoemaker, Project Manager for the Cosmic Explorer Project. “The unique insights of the UK team in both instrumentation and observational science are important ingredients in realizing our shared vision of Cosmic Explorer.”

“The Einstein Telescope project is now completing its preparation phase and moving towards implementation,” said Michele Punturo, spokesperson of the ET Scientific Collaboration. “The precious contribution of our UK colleagues, now supported by this grant, strengthens the ET collaboration and gives us confidence that ET’s ambitious goals will be achieved.”

Source: University of Southampton