Physicists from the ATLAS experiment, one of the four major experiments at CERN’s Large Hadron Collider (LHC) in Switzerland, have found the first direct evidence of high energy light-by-light scattering, a quantum-mechanical process that is forbidden in the classical theory of electrodynamics.
A candidate event of light-by-light scattering, a very rare process in which two photons interact and change direction, measured in the ATLAS detector. Image credit: CERN.
“This is a milestone result: the first direct evidence of light interacting with itself at high energy. This phenomenon is impossible in classical theories of electromagnetism; hence this result provides a sensitive test of our understanding of quantum electrodynamics (QED),” said Dr. Dan Tovey, ATLAS Physics Coordinator.
The direct evidence for light-by-light scattering at high energy had proven elusive for decades — until the LHC’s second run began in 2015.
As the accelerator collided lead ions at unprecedented collision rates, obtaining evidence for light-by-light scattering became a real possibility.
“This measurement has been of great interest to the heavy-ion and high-energy physics communities for several years, as calculations from several groups showed that we might achieve a significant signal by studying lead-ion collisions in Run 2,” explained Dr. Peter Steinberg, ATLAS Heavy Ion Physics Group Convener.
Heavy-ion collisions provide a uniquely clean environment to study light-by-light scattering.
As bunches of lead ions are accelerated, an enormous flux of surrounding photons is generated. When ions meet at the center of the ATLAS detector, very few collide, yet their surrounding photons can interact and scatter off one another. These interactions are known as ‘ultra-peripheral collisions.’
Studying more than 4 billion events taken in 2015, the ATLAS collaboration found 13 candidate events for light-by-light scattering.
This result has a significance of 4.4 standard deviations, allowing the team to report the first direct evidence of this phenomenon at high energy.
“Finding evidence of this rare signature required the development of a sensitive new ‘trigger’ for the ATLAS detector,” Dr. Steinberg said.
“The resulting signature — two photons in an otherwise empty detector — is almost the diametric opposite of the tremendously complicated events typically expected from lead nuclei collisions.”
“The new trigger’s success in selecting these events demonstrates the power and flexibility of the system, as well as the skill and expertise of the analysis and trigger groups who designed and developed it.”
The results were published online this week in the journal Nature Physics.
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M. Aaboud et al (ATLAS Collaboration). Evidence for light-by-light scattering in heavy-ion collisions with the ATLAS detector at the LHC. Nature Physics, published online August 14, 2017; doi: 10.1038/nphys4208
