Latest Articles for Particle Physics

Investigating how primordial black holes may contribute to dark matter formation.

ALPS II experiment seeks light particles to uncover mysteries of dark matter.

Research on polarized deuterons reveals details about gluons and nucleon interactions.

Discover how non-invertible symmetries reshape particle interactions in quantum field theories.

Research reveals how temperature impacts the X(4630) resonance and exotic hadron behavior.

Analyzing systematic uncertainties is key to improving particle physics measurements.

Discover the unique properties and formation of singly heavy pentaquarks.

A look into self-duality defects and fusion categories in modern physics.

Exploring new theories in particle physics focusing on scalar fields and dark matter.

A look into how neutron monitors measure cosmic rays and their variations.

Research examines dark matter and the universe's matter-antimatter imbalance through sterile neutrinos.

Exploring how non-invertible symmetries influence particle behavior in higher dimensions.

Research on bubble nuclei enhances knowledge of atomic structures and nuclear reactions.

A detailed look at cosmic rays and their role in galaxy clusters.

Research investigates unique properties of hidden-charm tetraquarks and their implications.

Researching semileptonic decays provides essential knowledge about quark interactions and fundamental forces.

A look at cosmic rays and their interaction with solar activity.

Research on high-energy collisions reveals patterns in particle behavior and correlations.

COSINE-100 has successfully reduced its detection threshold, improving dark matter research.

Exploring the role of cluster algebras in particle physics calculations.

Exploring the role of symmetries in advanced physics theories.

Researchers target the gauge-Higgs coupling to deepen particle physics insights.

Researchers use lattice QCD to uncover nucleon properties and their fundamental interactions.

Scientists use Shannon entropy to improve particle beam stability in accelerators.

Investigating Chern-Simons levels in unknown materials using anyons for quantum computing.

A new model seeks to connect neutrinos and dark matter in physics.

An overview of Feynman integrals and their role in quantum field theory.

Research on hadron interactions reveals key insights into particle behavior and fundamental forces.

B mesons hold keys to fundamental forces and physics beyond the Standard Model.

New techniques enhance energy measurement in particle physics.

Recent techniques aim to improve energy measurement in particle collisions.

This research investigates how mesons change in nuclear matter during proton collisions.

Researchers use levitated ferromagnets to seek evidence of ultralight dark matter.

Research reveals how dark matter influences the properties of neutron stars.

Scientists investigate axions as a possible form of dark matter.

New theories aim to connect neutrinos, dark matter, and the strong CP problem.

Researchers achieve stable entangled states using optical tweezers and ultracold polar molecules.

Research on the singly charged scalar singlet may address gaps in particle physics.

A study on quark-gluon plasma and how magnetic fields affect quarkonium behavior.

Examining the impact of quark AMM on dense quark matter in strong magnetic fields.