Latest Articles for High-Energy Collisions

Gaussian Mixture Models improve predictions in particle physics by addressing data tensions.

Scientists investigate W and Z bosons for clues about dark matter.

Investigating personalized amplitudes to enhance particle interaction models.

Study reveals the impact of charm quarks on particle production in high-energy collisions.

A new tool simulates DIS events, focusing on massive particles and neutrinos.

Researching charm particles from high-energy proton collisions for future physics experiments.

Using quantum computing to calculate parton fragmentation functions in particle physics.

Research reveals key mechanisms behind lepton pairs in heavy-ion collisions.

Belle II experiment investigates elusive Dark Photons and their role in dark matter.

Learn about hadron production and particle interactions in high-energy physics.

This paper presents the Unitary Toy Model for studying particle interactions.

Examining charm and bottom quarks reveals insights into hot matter created in collisions.

Study reveals how nuclear medium affects pion production in high-energy collisions.

Examining methods to analyze jets from high-energy particle collisions.

Exploring the discrepancies in soft photon production in particle collisions.

A search for a special particle called the stop in supersymmetry theory.

New framework improves analysis of particle collisions and systematic uncertainties.

Using neural networks to identify chiral magnetic waves in particle physics.

Fragmentation functions help explain hadron production in high-energy particle collisions.

A look into the nature of Hot QCD matter and its significance in physics.

Analyzing charmonium production in nuclear collisions through photon interactions and nuclear effects.

Exploring jet production in diffractive electron-proton collisions reveals important insights.

This article examines quarkonium production processes and their significance in particle physics.

Research reveals how mesons are created in extreme particle collisions.

Examining how kaons and antikaons interact in strange hadronic matter.

This research reveals key insights into quark-gluon plasma behavior during heavy ion collisions.

Investigating how elliptic flow reveals properties of Quark-Gluon Plasma.

3D pixel sensors enhance performance in radiation-rich environments of the LHC.

Research on top quark polarization offers insights into fundamental particle interactions.

Scientists observe neutrinos, improving understanding of particle physics and proton structure.

Study reveals how heavy flavor impacts particle fragmentation in collisions.

Scientists investigate light bosons, setting limits on their existence through high-energy collisions.

The MIParT model enhances jet tagging accuracy and efficiency in particle physics.

Research on J/ψ production helps reveal nuclear matter behavior during heavy-ion collisions.

Analyzing QCD corrections for accurate predictions of Higgs boson decays.

Research reveals how quarks and gluons behave under extreme conditions.

This research investigates long-lived particles using the ATLAS detector at CERN.

A study investigates the potential existence of dark photons at the Large Hadron Collider.

Quantum algorithms improve jet clustering, aiding particle physics research and data analysis.

A look at jet quenching and its relevance in quark-gluon plasma studies.