Latest Articles for Particle Physics

Examining how weakly interacting particles influence spin systems and superradiant interactions.

A new tool improves the modeling of gamma-ray behavior in the universe.

Study reveals key aspects of nucleon properties using advanced matrix element techniques.

New resonator design enhances axion search sensitivity by reducing mode mixing.

Researchers investigate B meson decay anomalies using the Two Higgs Doublet Model.

Explore the dense worlds of neutron stars and their complex matter.

This study examines how spin density changes in extreme conditions of particle collisions.

This study looks at how particle loss affects quantum entanglement.

Exploring the role of radiative symmetry breaking in mass generation and cosmic phenomena.

Energetic particles showcase complex behavior near interplanetary shocks, impacting our understanding of space.

Research reveals new insights into proton's inner workings using advanced techniques.

Scientists study charmed mesons to gain insights into the charm quark's properties.

A closer look at tetraquarks and their significance in particle physics.

The COMET experiment seeks to reveal new physics through muon interactions.

Discussing stable structures like kinks and double-kinks in two-dimensional field models.

Exploring the effects of electromagnetic and strong forces in proton-proton collisions.

Researching unusual particles to deepen our understanding of fundamental forces.

Examining the wave-like properties of dark matter and its cosmic implications.

This article explores axions and their connection to dark matter in the universe.

Scientists study axions through neutron stars to learn about dark matter and fundamental physics.

This article examines how fermions are produced during cosmic evolution.

Research investigates how different models affect cosmic ray shower images.

A study on the Supersymmetric Georgi-Machacek model and its implications for particle physics.

This research sheds light on semileptonic decays and charm quarks using BESIII data.

Investigating spin polarization of hyperons in particle collisions reveals insights into extreme matter conditions.

Neutrino oscillation reveals complex particle behavior affecting physics and cosmology.

Using machine learning to simplify scattering amplitudes in high-energy physics.

KATRIN enhances neutrino mass research using a new setup to reduce background noise.

A detailed look at beta functions in physics and their role in quartic interactions.

New methods improve precision in particle collision predictions.

A look into two-loop five-point Feynman integrals and their role in particle physics.

Exploring the relationship between gravitational waves and dark matter through advanced models.

This article explores tensor reduction techniques for simplifying complex Feynman integrals in particle physics.

Research reveals how pions and muons interact with argon atoms, enhancing detection methods.

NEON aims to uncover the origins of elusive cosmic neutrinos.

This study examines how temperature affects the movement of gold nanoparticles.

Research unveils how patchy particles can form unique quasicrystal structures.

Scientists are seeking elusive neutrinos at the Large Hadron Collider.

Researchers use machine learning to create data for particle physics more efficiently.

A theory explaining the unique traits of subdimensional particles like fractons.