Physics - High Energy Physics - Experiment

Researchers investigate light vector bosons to better understand particle physics and the universe.

Investigating diquarks to explain anomalies in particle physics.

JUNO aims to enhance detection of neutrinos from core-collapse supernovae.

Recent findings in neutrino physics may reshape our understanding of the universe.

Researchers improve particle identification during high-energy collisions using machine learning techniques.

Researchers investigate exotic tetraquarks that include strange quarks alongside charm quarks.

Researchers study particle distributions using normalized factorial moments in high-energy collisions.

Research at CEPC aims to uncover insights into quantum entanglement through Higgs boson decay.

Research reveals connections between event shape and particle production in proton collisions.

This article examines hadron production and the role of fragmentation functions.

An overview of Z boson production and decay at the LHC.

A study examines dark gauge bosons and their role in dark matter.

This study explores detecting axions through superfluid helium-3's nuclear spins.

Scientists investigate surprising findings suggesting potential new physics beyond the Standard Model.

Research reveals patterns in high-energy particle collisions and their interactions.

ATLAS is set to measure high-energy neutrinos from supernova explosions.

Research on neutrinos at the LHC opens new insights in particle physics.

NFLikelihood enables unsupervised learning of likelihoods, enhancing data analysis in physics.

A machine learning approach improves data quality monitoring in high-energy physics experiments.

Researchers improve predictions for heavy quarkonium production in particle collisions.

Research reveals how dark matter interacts with crystal structures, providing new detection strategies.

A look into particle physics and new methods for studying fundamental interactions.

Investigating rare particle decays with the Future Circular Collider offers new insights.

Researchers aim to detect low-mass particles influencing decay processes.

LST-1 telescope enhances detection of cosmic gamma-ray events through real-time data processing.

Scientists investigate dark neutrinos using the International Linear Collider.

Explore the functionality and applications of silicon photomultipliers in modern science.

Charm quark behavior in extreme conditions sheds light on fundamental particle interactions.

XENONnT experiment pushes boundaries in dark matter research with innovative electric field design.

This article examines new techniques for simulating light in particle physics.

A new framework enhances efficiency in high-energy physics experiments.

New algorithms enhance detection of primary vertices at the Large Hadron Collider.

Researchers are enhancing methods to detect dark matter particles using innovative systems.

Hyper-Kamiokande seeks to answer key questions about the universe through neutrino study.

CATHODE offers a fresh approach to finding new particles in collider experiments.

Recent research reveals new measurements of pion form factor and implications for muons.

Researchers investigate flavour-changing neutral currents in proton collisions at the LHC.

An analysis of ParticleNet and LCFIPlus for jet flavor identification at CEPC.

Enhancing haloscope performance through volume expansion and innovative designs.

Study reveals boosted decision trees excel in noisy data environments for anomaly detection.