A team of researchers have created matter solely from collisions of light particles…

A team led by researchers at Osaka University and University of California, San Diego has conducted simulations of creating matter solely from collisions of light particles. Their method circumvents what would otherwise be the intensity limitations of modern lasers and can be readily implemented by using presently available technology. This work might help experimentally test long-standing theories such as the Standard Model of particle physics, and possibly the need to revise them.

One of the most striking predictions of quantum physics is that matter can be generated solely from light (i.e., pH๏τons), and in fact, the astronomical bodies known as pulsars achieve this feat. Directly generating matter in this manner has not been achieved in a laboratory, but it would enable further testing of the theories of basic quantum physics and the fundamental composition of the universe.

In a study published in Physical Review Letters, a team led by researchers at Osaka University has simulated conditions that enable pH๏τon–pH๏τon collisions, solely by using lasers. The simplicity of the setup and ease of implementation at presently available laser intensities make it a promising candidate for near-future experimental implementation.

PH๏τon–pH๏τon collision is theorized to be a fundamental means by which matter is generated in the universe, and it arises from Einstein’s well-known equation E=mc2. In fact, researchers have indirectly produced matter from light: by high-speed acceleration of metal ions such as gold into one another. At such high speeds, each ion is surrounded by pH๏τons, and upon grazing past each other, matter and antimatter are produced.

matter from collision of pH๏τons only
Image of self-organized pH๏τon collider driven by an intense laser pulse propagating in a plasma. Credit: Yasuhiko Sentoku

However, it is challenging to produce matter experimentally in modern laboratories through the sole use of laser light because of the extremely high-power lasers required. Simulating how this feat might be achieved in a laboratory could bring about an experimental breakthrough, so that’s what the researchers set out to do.

“Our simulations demonstrate that, when interacting with the intense electromagnetic fields of the laser, dense plasma can self-organize to form a pH๏τon–pH๏τon collider,” explains Dr. Sugimoto, lead author of the study. “This collider contains a dense population of gamma rays, ten times denser than the density of electrons in the plasma and whose energy is a million times greater than the energy of the pH๏τons in the laser.”

matter from light particles only
Self-organized pH๏τon collider driven by an intense laser pulse (a) plasma density, (b) magnetic channel, (c) angular distribution of emitted pH๏τons. Credit: Physical Review Letters

PH๏τon–pH๏τon collisions in the collider produce electron–positron pairs, and the positrons are accelerated by a plasma electric field created by the laser. This results in a positron beam.

“This is the first simulation of accelerating positrons from the linear Breit–Wheeler process under relativistic conditions,” says Prof Arefiev, co-author of UCSD. “We feel that our proposal is experimentally feasible, and we look forward to real-world implementation.”

Dr. Vyacheslav Lukin, a program director at the US National Science Foundation which supported the work, says, “This research shows a potential way to explore the mysteries of the universe in a laboratory setting. The future possibilities at today’s and tomorrow’s high-power laser facilities just became even more intriguing.”

Applications of this work to the fictional matter–energy conversion technology of Star Trek remain just that: fiction. Nevertheless, this work has the potential to help experimentally confirm theories of the composition of the universe, or perhaps even help discover previously unknown physics.

Reference:

K. Sugimoto et al, Positron Generation and Acceleration in a Self-Organized PH๏τon Collider Enabled by an Ultraintense Laser Pulse, Physical Review Letters (2023). DOI: 10.1103/PhysRevLett.131.065102

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