Breakthrough in Development of Gamma-Ray Lasers – Useful in Medicine and Spacecraft Propulsion
Allen Mills is a professor in the University of California Riverside Department of Physics and Astronomy. Credit: I. Pittalwala, UC RiversideCalculations by University of California Riverside’s Allen Mills predict metastable positronium bubbles in liquid helium.
A physicist at the University of California, Riverside, has performed calculations showing hollow spherical bubbles filled with a gas of positronium atoms are stable in liquid helium.
The calculations take scientists a step closer to realizing a gamma-ray laser, which may have applications in medical imaging, spacecraft propulsion, and cancer treatment.
Extremely short-lived and only briefly stable, positronium is a hydrogen-like atom and a mixture of matter and antimatter — specifically, bound states of electrons and their antiparticles called positrons. To create a gamma-ray laser beam, positronium needs to be in a state called a Bose-Einstein condensate — a collection of positronium atoms in the same quantum state, allowing for more interactions and gamma radiation. Such a condensate is the key ingredient of a gamma-ray laser.
“My calculations show that a bubble in liquid helium containing a million atoms of positronium would have a number density six times that of ordinary air and would exist as a matter-antimatter Bose-Einstein condensate,” said Allen Mills, a professor in the Department of Physics and Astronomy and sole author of the study that was published December 6, 2019, in the journal Physical Review A.
Helium, the second-most abundant element in the universe, exists in liquid form only at extremely low temperatures. Mills explained helium has a negative affinity for positronium; bubbles form in liquid helium because helium repels positronium. Positronium’s long lifetime in liquid helium was first reported in 1957.
When an electron meets a positron, their mutual annihilation could be one outcome, accompanied by the production of a powerful and energetic type of electromagnetic radiation called gamma radiation. A second outcome is the formation of positronium.
Mills, who directs the Positron Laboratory at UC Riverside, said the lab is configuring an antimatter beam in a quest to produce the exotic bubbles in liquid helium that Mills’ calculations predict. Such bubbles could serve as a source of positronium Bose-Einstein condensates.
“Near term results of our experiments could be the observation of positronium tunneling through a graphene sheet, which is impervious to all ordinary matter atoms, including helium, as well as the formation of a positronium atom laser beam with possible quantum computing applications,” Mills said.
Reference: “Positronium Bose-Einstein condensation in liquid 4He bubbles” by A. P. Mills, Jr., 6 December 2019, Physical Review A.
The research was supported by the National Science Foundation.
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