Hunting for dark matter and abstract painting are all in a day’s work for Raghda Abdel Khaleq, a PhD researcher in nuclear physics.
Raghda Abdel Khaleq spends a lot of time contemplating the unknown sector of our universe. And not just for her PhD research in nuclear physics.
“This painting is part of a dark energy-inspired series,” she says, as she makes another deliberate stroke of the paintbrush on her canvas. “I’m exploring the repulsive energy that is responsible for the universe expanding at an accelerated rate.
“I love the creative liberty of choosing how to represent a scientific idea.”
Before arriving at The Australian National University Research School of Physics, Raghda explored the connections between art and science through undergraduate degrees in fine arts and advanced science.
Now she is part of the ARC Centre of Excellence for Dark Matter Particle Physics, where she is helping to unlock one of the greatest mysteries of our universe, by theorising how dark matter particles could interact with the nucleus of an atom.
Dark matter and dark energy represent the part of the universe that we can’t see – which, combined, is 95 per cent of it.
Dark energy drives the accelerated expansion of our universe, Raghda explains.
“If we look at a faraway galaxy or faraway supernova, we can see that over time, the spectrum of light is red shifted. This indicates that the universe is expanding at an accelerated rate.”
Raghda uses a range of red tones and gradients to explore this mystery through art.
“For me, red represents this red shifting phenomenon, with the darker reds representing greater expansion.”
Raghda Abdel Khaleq. Photo: Nic Vevers/ANU
Dark matter is like dark energy, in that scientists can measure its impact on the universe, but we haven’t been able to detect or observe it directly. However, we do know that dark matter has mass and impacts the way galaxies are formed.
Australia is playing a leading role in the global hunt for dark matter, with the Stawell Underground Physics Laboratory, located in a gold mine one kilometre underground.
“We want to try and detect a dark matter particle interacting with a nucleus and giving off a signal.
“I am looking at this from the lens of a nuclear physicist, investigating the nucleus that the dark matter particle is going to scatter off.”
Raghda hopes that both her research and her art practice can help elucidate scientific concepts that are difficult to understand.
“I don’t think it is possible to fully explain something scientific through just one piece of artwork. But I do think that art and creative media can help people get a little bit of intuition into some difficult concepts.”
Raghda hopes to use her PhD for future creative inspiration.
This article first appeared at the ANU College of Science.
ANU is home to one of the world’s most innovative nuclear science facilities and programs. This work is helping protect environmental treasures like the world’s largest coral reef, understand the origins of life on our planet and launch tech into space.
Nuclear submarines can go for decades without refuelling, making them faster, stealthier and much more expensive than conventional submarines.
From exploring the mysteries of dark matter, to planting the seeds of human life away from Earth, Lachlan McKie is using nuclear science to solve some of our most complex questions.