Latest Articles for Particle Physics

Quark saturation is key to understanding extreme matter states in physics.

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

Researchers enhance knowledge of mesons using advanced techniques and theoretical methods.

Examining how charmed baryons respond to varying temperature and density.

Discover the fascinating process of vacuum pair production and its implications.

A look into methods for identifying potential new particles in particle physics.

Scientists push boundaries in axion detection, shedding light on dark matter.

An overview of baryon behavior during state transitions and their significance.

Investigating the complexities of tunneling time in quantum mechanics.

This article explores the significance of heavy quarkonia in particle physics.

A look into the complexities of heterotic string theory and its implications.

Exploring how moving boundaries influence particle creation in quantum vacuum fluctuations.

Explore the fascinating world of quantum entanglement and its implications.

Exploring the connection between minimal entanglement and symmetry in particle interactions.

A detailed look into the 331 model and its implications for quark interactions.

Researching dark photons helps explore the early universe and dark matter.

Innovative light guide designs enhance energy measurement in SpaCal calorimeters.

Examining how magnetic fields influence particle orbits near specific black holes.

Study reveals how bosons and fermions behave under classical forces.

An overview of massless chiral fields and their significance in theoretical physics.

Scientists investigate vectorlike quarks and heavy Higgs bosons in particle physics.

Research on charmonium reveals properties of matter formed in heavy-ion collisions.

MATHUSLA aims to reveal dark matter and its elusive long-lived particles.

Researchers investigate mediators linking dark matter and ordinary matter through experiments.

Investigating how heavy-flavor jets behave in high-energy nuclear collisions.

Exploring how acceleration alters particle observation in physics.

This study explores how charged particles interact during high-energy collisions.

New insights reveal how localized ULF waves affect particles in the magnetosphere.

Studying T-odd observables reveals insights into top quark interactions and potential new physics.

Research explores quantum gravity's influence on neutrinos and dark matter interactions.

Exploring a model linking neutrinos and dark matter without supersymmetry.

Research reveals key patterns in baryon and anti-baryon behavior during high-energy collisions.

This article explores the Dunkl-Klein-Gordon equation's impact on quantum systems.

Researchers enhance particle modeling techniques using machine learning methods.

An exploration of how fermions and bosons behave in beamsplitters and interferometers.

Exploring charmonium decays reveals key information about particle interactions.

Investigating axion-like particles may shed light on dark matter and the Hubble tension.

Scientists observe antiproton annihilation at rest in argon, advancing particle physics.

New techniques improve simulations of the Schwinger model using quantum computing.

This study focuses on detecting long-lived particles to uncover new physics.