Physics - High Energy Physics - Phenomenology

Researchers investigate dark matter's self-interactions to address key issues in current models.

Neutrinos are tiny particles with big implications for our universe.

Scientists investigate dark matter through axions generated in the Sun.

Research reveals how nuclear structures affect particle behaviors in high-energy collisions.

Investigating rare particle decays to uncover potential new physics beyond the Standard Model.

Researchers investigate gluon density and model challenges in particle physics.

Research highlights improvements in measuring meson decay constants using advanced simulations.

Exploring dark matter candidates and their roles in modern physics.

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

Researchers analyze particle jets to learn about quark-gluon plasma properties.

Scientists investigate axions to uncover dark matter’s mysteries and advance physics.

Research reveals how neutrinos affect supernovae and neutron star mergers.

New insights on millicharged dark matter's role in high-energy neutrinos from the Sun.

Investigating high-energy neutrinos from binary neutron star collisions and their cosmic implications.

A novel approach to efficient particle collision simulations using machine learning techniques.

Neutrinoless double beta decay may reveal insights into neutrinos and new particle physics.

Exploring particle interactions, especially the Higgs boson pair production, in high-energy environments.

This article discusses wave behavior in curved spaces and its significance in physics.

Scientists use pulsar timing arrays to study gravitational waves and their effects.

Scientists aim to detect particles that may explain Dark Matter.

This article examines how neutrinos interact with oxygen and the significance of these reactions.

Research reveals how mesons are created in extreme particle collisions.

Analyzing how multiple Higgs doublets affect particle interactions and symmetries.

An overview of the Chameleon mechanism in scalar nonmetricity cosmology.

Research reveals how gluons affect proton structure and particle interactions.

Research bridges dark matter and neutrinos, revealing new possibilities in particle physics.

Examining how kaons and antikaons interact in strange hadronic matter.

Research explores how vortex states affect neutron decay processes.

Research focuses on spin behavior of vector mesons in high-energy collisions.

A look into the electromagnetic properties of pseudoscalar mesons.

Research on Quark-Gluon Plasma reveals conditions similar to the early universe.

Research focuses on how electric and chiral charges affect light emission in QGP.

Recent findings suggest potential new particles in Higgs boson data.

Scientists seek ultrashort gamma-ray bursts to understand dark matter interactions.

Exploring new cutting rules for quantum fields in cosmology.

Scientists investigate how non-standard neutrino interactions affect supernova observations.

Scientists examine light nuclei production during ultraperipheral collisions and photon interactions.

A fresh look at the universe's early expansion through Warm Inflation theory.

Exotic hadrons challenge current theories in particle physics through complex quark arrangements.

This article explores the significance of complete monotonicity in particle interactions.