Latest Articles for High-energy Physics

Research on charmed hadrons reveals insights into high-energy nuclear collisions and quark-gluon plasma.

Machine learning transforms event reconstruction in particle physics, improving accuracy and efficiency.

Research uncovers details on excited hyperons, advancing knowledge in particle physics.

This study reveals the behaviors of charmonium states under extreme conditions.

Research sheds light on cosmic ray sources and their gamma-ray emissions.

A deep dive into the phases and critical points of Quantum Chromodynamics.

This article examines a fresh approach to Higgs boson and top quark behavior.

Research into lepton flavor violation aims to uncover new particles and interactions.

Investigating how energy and clustering affect nuclear phase transitions during heavy-ion collisions.

A new system uses machine learning to improve data quality monitoring in experiments.

Explore the fascinating interactions between monopoles and fermions in high-energy physics.

Examining the role of perturbations in cosmic evolution and inflation.

An overview of black holes and their fascinating accretion disks.

Researchers study jet production in deep inelastic scattering to test quantum chromodynamics.

A look into dipole orientation effects on particle interactions at high energies.

New methods enhance understanding of soft theorem in QCD up to three loops.

New findings link HAWC J1844-034 to cosmic rays and nearby pulsars.

Exploring superspin chains and their significance in physics and quantum computing.

Exploring the formation and implications of global monopoles in the two-Higgs-doublet model.

Explore cosmic ray origins and behaviors through advanced simulations.

Examining how spin influences entropy in relativistic hydrodynamics.

Improvements in energy measurement accuracy for electrons and photons at the ATLAS detector.

New models explore stability of the weak scale in high energy physics.

A new model improves particle jet tagging accuracy using advanced graph techniques.

Exploring the impact of quantum computing on simulating particle interactions in QCD.

A new method connects high-energy neutrinos with their gamma-ray sources for better observations.

Exploring how non-local effects reshape our understanding of quantum electrodynamics.

A look into how asymptotic safety could reshape our understanding of high-energy physics.

A look at enhancing ROOT with SYCL for efficient data analysis.

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

Research investigates CP violation in charmed decays to understand matter-antimatter imbalance.

Researchers improve predictions for heavy quarkonium production in particle collisions.

An overview of efforts to accelerate positrons in plasma wakefields.

Exploring how new models reshape our understanding of fundamental particles.

New detection systems aim to improve cosmic event analysis.

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

New methods enhance precision in particle physics calculations and address challenges.

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

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

Researchers study neutron density fluctuations in heavy-ion collisions to understand matter's fundamental nature.