World's top research institutes join hands to find 'mysterious' Big Bang particle
Scientists at the University of Huddersfield are working with experts at some of the world's leading research institutes to unravel the mysteries of a particle that played a role in the creation of the universe.
The existence of neutrinos and anti-neutrinos - particles that are almost massless and which travel at light speed from one side of the earth to the other - was confirmed more than 50 years ago. Scientists believe that they were created at the Big Bang and might hold the key to the nature of the universe.
But they are light particles that react weakly with matter and they change properties as they travel. This process -named neutrino oscillation - makes the particles highly elusive.
"To study them you have to produce them at very high rates and my research is all about maximising anti-neutrino production," said Dr Adriana Bungau, a research fellow at the University of Huddersfield and a member of its International Institute for Accelerator Applications.
Dr Bungau is part of an international project to design and construct a new accelerator, which will use a low-energy cyclotron to direct proton beams at a target consisting of a cylinder of beryllium-9, itself surrounded by a refrigerator-sized cylinder of lithium-7. This would result in the continuous creation of lithium-8 isotopes that would rapidly decay, producing huge numbers of anti-neutrinos, which could then be used in practical experiments.
Dr Bungau and University of Huddersfield colleagues are working with international partners on design and funding proposals for the new facility, probably to be built in Japan, which already has a neutrino-detector named KamLAND.
Other participants in the project include the Massachusetts Institute of Technology and Columbia University in New York, plus the Paul Scherrer Institute in Switzerland and the Institute Internationale Frascati in Italy.
Dr Bungau's role is to design the target and surrounding components by carrying out intensive computer simulations.
"We have come up with an optimum design in order to get a higher rate of lithium-8. We did that by surrounding the target with heavy water, which means that the neutrons which were chipped off by the proton impact are slowed down to very low energies, so they can be captured in the surrounding environment made of lithium-7," Dr Bungau explained.
This results in a tenfold increase in lithium-8 production, according to Dr Bungau, although she is aiming for more as the project progresses.
She believes passionately that improved understanding of particles will open up fresh horizons.
An article dealing with her research has recently been published in the leading journal Physical Review Letters.