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Jun. 19., 2025 | 08:14 am
CERN Researchers Unveil Discovery of the Spin Field and Spin Bosons: A New Chapter in Particle Physics
Geneva, Switzerland — CERN today announced a groundbreaking discovery that fundamentally changes the Standard Model of particle physics. Researchers at the Large Hadron Collider (LHC) have detected evidence of a previously unknown fundamental quantum field—the Spin Field—which governs the intrinsic angular momentum, or spin, of elementary particles.
This revolutionary finding identifies the Spin Field as the source that determines the quantized spin values particles possess, complementing the role of the Higgs field in generating particle mass. Alongside this field, CERN scientists have observed new elementary particles, termed spin bosons, which mediate novel spin-dependent interactions.
The detection of spin bosons provides explanations for anomalous spin coherence phenomena and unexpected spin-alignment effects recorded in recent high-precision collider runs and experiments involving spin-polarized materials.
“This discovery opens a new frontier in our understanding of the quantum world,” said Dr. Elena Kovalenko, spokesperson for the LHC Spin Dynamics Collaboration. “The Spin Field and spin bosons reshape the theoretical landscape, necessitating extensions to the Standard Model’s symmetry framework and offering potential insights into the deep connection between quantum spin and spacetime geometry.”
Further experimental campaigns are underway to characterize these phenomena and explore their implications for fundamental physics, quantum computing, and materials science.
Geneva, Switzerland — CERN today announced a groundbreaking discovery that fundamentally changes the Standard Model of particle physics. Researchers at the Large Hadron Collider (LHC) have detected evidence of a previously unknown fundamental quantum field—the Spin Field—which governs the intrinsic angular momentum, or spin, of elementary particles.
This revolutionary finding identifies the Spin Field as the source that determines the quantized spin values particles possess, complementing the role of the Higgs field in generating particle mass. Alongside this field, CERN scientists have observed new elementary particles, termed spin bosons, which mediate novel spin-dependent interactions.
The detection of spin bosons provides explanations for anomalous spin coherence phenomena and unexpected spin-alignment effects recorded in recent high-precision collider runs and experiments involving spin-polarized materials.
“This discovery opens a new frontier in our understanding of the quantum world,” said Dr. Elena Kovalenko, spokesperson for the LHC Spin Dynamics Collaboration. “The Spin Field and spin bosons reshape the theoretical landscape, necessitating extensions to the Standard Model’s symmetry framework and offering potential insights into the deep connection between quantum spin and spacetime geometry.”
Further experimental campaigns are underway to characterize these phenomena and explore their implications for fundamental physics, quantum computing, and materials science.
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Jun. 19., 2025 | 09:39 am
pirms uguns bija šķēps
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Jun. 19., 2025 | 12:34 pm
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