Latest Articles for Particle Physics

Researchers seek new particles to answer fundamental questions in particle physics.

Innovative techniques improve data extraction in high-energy physics experiments.

A proposed model explains how lighter particles gain mass through symmetry and quantum corrections.

Baryons and tetraquarks reveal insights about matter and fundamental forces.

New findings on reactor antineutrinos challenge existing nuclear data predictions.

The FASER experiment at LHC searches for dark photons linked to dark matter.

Researchers investigate the flavon to understand particle mass and physics mysteries.

New insights into tetraquarks reveal complex interactions and stability factors.

Muon colliders could revolutionize our understanding of the Top Yukawa coupling and the Higgs boson.

Explore the forces and particles shaping nucleon interactions within atomic nuclei.

Researchers uncover unusual decay patterns in light hadrons, hinting at new particle states.

Research investigates unique features of Oxygen-Oxygen collisions and their significance.

Enhancing accuracy in particle decay simulations is essential for particle physics research.

Recent studies delve into the magnetic properties of the positive muon and its anomalies.

A look into the Higgs boson mass and its implications for particle physics.

This article discusses Higgs boson rare decay processes and their implications for particle physics.

A breakdown of gluon scattering and its significance in particle interactions.

Research on X17 particle reveals exciting insights into nuclear physics.

Recent findings shed light on diquarks' role in charm baryon production.

Exploring how cell shapes affect their movement and interactions in living systems.

A look into the strong force and its role in hadron structure.

A look at how theoretical models explain quark confinement in particle physics.

Research on rare events faces challenges from background noise and uncertainty.

New staggered designs improve particle detection accuracy in calorimeters.

LCLS-II-HE upgrades utilize machine learning for precise optical alignment and enhanced X-ray experiments.

Investigating how gravity influences quantum systems and the quest for quantum gravity.

Research reveals how rotation affects quark behavior and confinement at high energy.

Researchers study heavy neutrinos to understand their role in particle physics.

RNO-G aims to enhance our knowledge of high-energy cosmic events through neutrino detection.

ATLAS collaboration achieves remarkable accuracy in measuring the Higgs boson mass.

Discover how neutrinos reveal the origins of ultrahigh energy cosmic rays.

Scientists investigate sources of cosmic rays and their energy loss mechanisms.

Research on higher mesons sheds light on particle interactions and the strong force.

Scientists delve into the intriguing world of six-quark particles called dibaryons.

A study focused on quarkonium production from heavy atomic nuclei collisions.

Investigating drag force and potential energy in rotating quark-gluon plasma.

Examining the role of chiral gauge theories in particle physics dynamics.

Examining how a light boson influences the early universe and cosmic microwave background.

An overview of quarks, clusters, and the fascinating states of quark matter.

Research reveals mesons' behavior in nuclear environments, focusing on eta and eta-prime.