alice-antimatter-hyperhelium4-evidence-lhc
ALICE Unveils First Evidence of Antimatter Hyperhelium-4 Partner
Introduction: The Role of the Large Hadron Collider (LHC)
The Large Hadron Collider (LHC) facilitates collisions between heavy ions, generating quark—gluon plasma—a hot, dense state of matter believed to have existed a millionth of a second after the Big Bang. These collisions also offer an ideal environment for the formation of atomic nuclei, exotic hypernuclei, and their antimatter equivalents, including antinuclei and antihypernuclei.
Importance of Hypernuclei Research
The study of these matter forms is vital for multiple objectives, including:
- Deciphering how hadrons emerge from quarks and gluons in the plasma
- Exploring the matter-antimatter imbalance in the universe today
What are Hypernuclei?
Exotic Nuclear Structures
Hypernuclei are exotic nuclear structures composed of protons, neutrons, and hyperons—unstable particles that include one or more strange quarks. Despite their discovery in cosmic rays over 70 years ago, hypernuclei continue to captivate physicists due to their rarity in nature and the challenges associated with their creation and study in laboratory settings.
Hypernuclei Production in Heavy-Ion Collisions
Hypernuclei are produced in substantial numbers during heavy-ion collisions; however, until recently, only the lightest hypernucleus, the hypertriton, and its antimatter counterpart, the antihypertrition, have been detected. The hypertrition consists of a proton, a neutron, and a lambda particle (a hyperon with one strange quark), while the antihypertrition is composed of an antiproton, an antineutron, and an antilambda.
Antimatter Hypernuclei: A Milestone Discovery
First Evidence of Antihyperhelium-4
After the STAR collaboration at the Relativistic Heavy Ion Collider (RHIC) reported the observation of antihyperhydrogen-4 earlier this year—a bound state comprising an antiproton, two antineutrons, and an antilambda-the ALICE collaboration at the LHC has now provided the first evidence of antihyperhelium-4. This exotic particle is made up of two antiprotons, an antineutron, and an antilambda.
Significance of the Discovery
This result, showing a significance of 3.5 standard deviations, marks the first evidence of the heaviest antimatter hypernucleus observed at the LHC. The findings have been made available on the arXiv preprint server.
ALICE Experiment and Methodology
The 2018 Lead-Lead Collision Data
The ALICE experiment utilized lead-lead collision data from 2018, with an energy of 5.02 teraelectronvolts (TeV) for each colliding pair of nucleons (protons and neutrons). Employing an advanced machine-learning technique that exceeds the performance of standard hypernuclei search approaches, ALICE researchers examined the data for signs of hyperhydrogen-4, hyperhelium-4, and their antimatter equivalents.
Detection and Analysis Process
To identify candidates for (anti) hyperhydrogen-4, researchers searched for the (anti) helium-4 nucleus and the charged pion produced during its decay. In contrast, candidates for (anti) hy perhelium-4 were detected through their decay into an (anti) helium-3 nucleus, an (anti) proton, and a charged pion.
Measured Masses and Production Yields of Hypernuclei
Consistency with World-Average Values
The ALICE team not only found evidence of antihyperhelium-4 a significance of 3.5 standard deviations and antihyperhydrogen-4 with a significance of 4.5 standard deviations, but also measured the production yields and masses of both hypernuclei.
Both hypernuclei showed measured masses that are consistent with the current world-average values. The production yields were also analyzed and compared with predictions made by the statistical hadronization model, which accurately depicts hadron and nucleus formation in heavy-ion collisions.
Statistical Hadronization Model Predictions
The comparison shows that the statistical hadronization model's predictions are consistent with the data when both excited and ground states of hypernuclei are factored in. This supports the model's effectiveness in describing hypernuclei production, which are small, dense entities measuring roughly 2 femtometers in diameter (with 1 femtometer equal to 10¯¹⁵ meters).
Conclusion: Contribution to Understanding Matter and Antimatter
The researchers measured the antiparticle-to-particle yield ratios for both hypernuclei and found them to be consistent with unity, within the bounds of experimental uncertainty. This consistency aligns with ALICE's findings of equal matter and antimatter production at LHC energies and contributes to the broader study of the matter-antimatter imbalance in the universe.
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Labels: ALICE experiment, Antihyperhelium, Antimatter, Hypernuclei, LHC, Particle Physics, Quantum Physics, Science Discovery