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The research has "changed the way we think about the structure of the proton," one scientist said.
Physics at the smallest scales is a challenge of observation: Particles are often fleeting, and the forces that govern their behavior are nearly imperceptible. But now, by exploiting decades-old data and a 50-year-old prediction about gravity’s import on subatomic particles, a team of physicists has teased out a measurement for a second mechanical property in the proton.
Let’s slow down for a moment. A proton is a particle that, along with neutrons and electrons, makes up an atom. Protons themselves are made of even tinier particles called quarks. These quarks glom together thanks to the strong force, one of the four fundamental forces. (The other three are gravity, the weak force, and electromagnetism.) The recent team successfully measured the strong force’s distribution within the proton, revealing the shear stress on the proton’s quarks.
“At its peak, this is more than a four-ton force that one would have to apply to a quark to pull it out of the proton,” said Volker Burkert, principal staff scientist at Jefferson Lab and the study’s lead author, in a lab release.
Published in Reviews of Modern Physics, the work follows up on a 2018 measurement of the proton’s internal pressure. The data the team studied came out of experiments at Jefferson Lab’s Continuous Electron Beam Accelerator Facility, or CEBAF, and the researchers used something called ‘deeply virtual Compton scattering’ (DVCS) to take the measurement. In DVCS, a high-energy electron is beamed at a target hydrogen proton. A quark within the proton emits a photon, which carries information about the quark’s properties. DVCS also yields information on gravity’s effects on matter, an idea developed in the early 2000s by the physicist Maxim Polyakov.
Physics at the smallest scales is a challenge of observation: Particles are often fleeting, and the forces that govern their behavior are nearly imperceptible. But now, by exploiting decades-old data and a 50-year-old prediction about gravity’s import on subatomic particles, a team of physicists has teased out a measurement for a second mechanical property in the proton.
Let’s slow down for a moment. A proton is a particle that, along with neutrons and electrons, makes up an atom. Protons themselves are made of even tinier particles called quarks. These quarks glom together thanks to the strong force, one of the four fundamental forces. (The other three are gravity, the weak force, and electromagnetism.) The recent team successfully measured the strong force’s distribution within the proton, revealing the shear stress on the proton’s quarks.
“At its peak, this is more than a four-ton force that one would have to apply to a quark to pull it out of the proton,” said Volker Burkert, principal staff scientist at Jefferson Lab and the study’s lead author, in a lab release.
Published in Reviews of Modern Physics, the work follows up on a 2018 measurement of the proton’s internal pressure. The data the team studied came out of experiments at Jefferson Lab’s Continuous Electron Beam Accelerator Facility, or CEBAF, and the researchers used something called ‘deeply virtual Compton scattering’ (DVCS) to take the measurement. In DVCS, a high-energy electron is beamed at a target hydrogen proton. A quark within the proton emits a photon, which carries information about the quark’s properties. DVCS also yields information on gravity’s effects on matter, an idea developed in the early 2000s by the physicist Maxim Polyakov.
Physicists Just Learned Something Major About the Proton
The research has "changed the way we think about the structure of the proton," one scientist said.
gizmodo.com