Latest Articles for Particle Physics

Scientists enhance energy measurements using dual-readout techniques in particle physics.

Investigating the origins and behavior of superheavy dark matter in the universe.

Leptoquarks may explain anomalies in lepton dipole moments and reveal new physics.

Investigating tau neutrinos and their interactions to reveal fundamental physics.

The EIC aims to deepen our knowledge of matter's fundamental particles.

A machine learning method improves synchrotron magnetic field modeling.

Examining the interplay of forces in particle physics through kinetic mixing.

A collection of simulated jets for advancing machine-learning applications in particle physics.

Researchers investigate axion-like particles to address mysteries in physics and dark matter.

Research on heavy flavor quarks in nuclear environments reveals insights into heavy-ion collisions.

Scientists study exotic particles that combine different quarks, challenging current physics models.

New methods enhance predictions for nuclear fission processes and behaviors.

A study evaluates MSHT and NNPDF methods for fitting parton distribution functions.

New experimental techniques enhance insights into scalar meson properties via photoproduction.

This article discusses advancements in understanding nucleon interactions in nuclear physics.

New methods improve the accuracy of photon PDF for particle physics.

A look into pair production of Higgs bosons and associated particle interactions.

Uncovering the secrets of dark matter through neutron stars and black holes.

New findings on heavy quark diffusion in different plasma types reveal important transport properties.

Researching lepton content in protons through high-energy collisions.

This article explores the significance and implications of neutral triple gauge couplings.

Investigating a theoretical model for dark matter involving singlet-doublet fermions.

A fresh approach to understanding quark-gluon plasma in heavy-ion collisions.

This study uses machine learning to identify strange-quark jets and improve fragmentation tagging.

A study on color superconductivity and its effects on quark matter.

Studying gamma rays and axion-like particles to understand cosmic interactions.

Delving into the strong CP problem and its possible solutions in particle physics.

New observations link neutrinos to high-energy gamma rays in our galaxy.

Research reveals properties of beryllium and helium hypernuclei through advanced models.

Investigating multi-Higgs production and gravitational waves to reveal new physics beyond the Standard Model.

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.