Physics - High Energy Physics - Experiment

RS3L enhances model training using re-simulation techniques in high-energy physics.

Examining the Minimal Left-Right Symmetric Model in particle physics.

New findings shed light on kaon pair behavior during particle decay.

Investigating the reheating mechanisms of neutron stars and their astrophysical implications.

Examining neutron decay reveals insights into particle interactions and potential new physics.

A tutorial for advanced students on analyzing LHC particle physics data.

This study investigates light particles that might decay into jets using ATLAS data.

Discover how nuclear shadowing affects particle interactions in high-energy physics.

Recent measurements of cosmic-ray muons enhance understanding of particle physics and neutrino behavior.

Research reveals potential pathways for understanding new physics through cLFV.

Researchers analyze top quark and photon interactions for insights into particle physics.

Investigating particle collisions to uncover fundamental physics and new phenomena.

A novel technique using atom interferometry seeks precise measurement of a fundamental physics constant.

Researchers analyze charge and baryon balance functions in proton-proton collisions.

New experiments aim to reveal the secrets of dark matter and dark energy.

This article reviews the LS-2HDM and its implications on the W-boson mass measurement.

New simulation techniques enhance our understanding of electroweak production at colliders.

This article explores the significance of muons in understanding cosmic rays.

Artificial intelligence enhances the analysis of particle collisions and jets in HEP.

NuGraph2 enhances the study of neutrino interactions using advanced graph neural networks.

A new detector improves sensitivity for particle measurement using innovative water-based technology.

Scientists measure vector boson production in high-energy proton collisions at LHC.

Research examines potential changes in particle types and implications for physics.

Research discusses the difficulties in identifying dark photons and improving detection methods.

A new software approach helps reduce radon noise in dark matter detection.

Examining the performance of the CMS electromagnetic calorimeter from 2015 to 2018.

Research explores how neutrinos from supernovae can reveal secrets of dark matter.

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

Study examines electroweak boson pair production in proton-proton collisions.

Study measures boson production in proton collisions, enhancing our knowledge of particle physics.

New measurements enhance our understanding of the Higgs boson mass and width.

A study investigates heavy Majorana neutrinos using data from the Large Hadron Collider.

ATLAS leverages cloud resources to enhance data analysis and efficiency in particle physics.

New model enhances calorimeter simulation efficiency and accuracy with machine learning techniques.

Exploring the behavior of neutrinos and their implications in astrophysics.

Research focuses on heavy particles decaying into Higgs bosons at the LHC.

Study measures particle interactions and searches for exotic states in collisions.

A new method improves identification of heavy-flavored jets in collider physics.

Scientists discuss recent findings on meson decays and lepton behavior.

Recent hydrogen studies shed light on fundamental physics and matter-antimatter differences.