Latest Articles for High-Energy Experiments

Examining the future challenges of event generators in high-energy physics.

Deep learning methods improve particle identification and data analysis at the LHC.

Research reveals how light nuclei form in extreme conditions of heavy ion collisions.

A new method improves event classification in particle physics using machine learning.

A new approach improves models for particle interactions in high-energy physics.

Research introduces unbiased phase factor to enhance understanding of QCD behaviors.

The Triplet Track Trigger improves data collection in high-energy physics experiments.

Researchers are turning to Bayesian methods for better data analysis at the LHC.

A new method enhances the analysis of short-lived particles in high-energy physics.

Scientists study rare particle decays to explore fundamental forces in the universe.

Study of how particles are produced during high-energy collisions and its implications.

Investigating how gauge fields respond to constant electric and magnetic backgrounds.

New research reveals complex interactions in scalar fields and vacuum decay.

Researchers investigate long-lived particles at the LHC, finding no significant evidence yet.

A new machine learning method improves particle event analysis in high-energy physics.

Examining how the Higgs boson decays into pairs of leptons.

Examining particle collisions reveals key information about hadrons and internal structure of protons.

Examining the intriguing role of magnetic monopoles in particle physics.

Plasma screening influences electron behavior and atomic transitions in dense plasma environments.

A novel approach enhances the identification of rare events in particle collisions.

This article examines spin correlation and entanglement in top quark experiments.

Research reveals how nuclear structures affect particle behaviors in high-energy collisions.

Research at Hall D is revealing new insights into nuclear and particle physics.

New methods improve identification and analysis of tau leptons in particle physics.

Recent LHC experiments reveal insights into the elusive nature of neutrinos.

This article discusses leptogenesis and right-handed neutrinos' role in matter creation.

PICOSEC detectors improve timing in particle physics experiments with precision under challenging conditions.

A model presents new particles to explain surprising mass measurements.

A new machine learning approach improves data quality monitoring in particle physics.

Scientists investigate the role of right-handed neutrinos in understanding neutrino mass.

Examining how final state interactions influence scattering processes in particle physics.

This study examines how positively charged kaons interact with argon in high-energy experiments.

LUXE investigates light and matter under high electric fields to study particle creation.

Exploring how natural supersymmetry aims to clarify particle physics and the Higgs boson.

Exploring the significance of lepton number violation and neutrinoless double beta decay in particle physics.

Researchers probe boson production with photons, revealing crucial interactions in particle physics.

Research sheds light on the stability of exotic tetraquarks and their binding energies.

Exploring a key function vital for particle collision analysis.

A look into top quark tagging and its significance in particle physics.

This model expands the Higgs sector with additional scalar fields to explain particle mass.