Latest Articles for Nuclear Physics

This article explores the role of seniority in nuclear interactions and recent findings.

Research reveals interactions between charm and strange dibaryons through lattice QCD methods.

A look into how fission fragments spin and vibrate during nuclear reactions.

Learn about rare beta decay processes and their significance in nuclear physics.

Recent findings reveal insights into particle jets from lead-lead collisions.

Discover recent developments in nuclear masses and fission barriers using the liquid drop model.

Investigating how magnetars produce and maintain their powerful magnetic fields.

New techniques improve atomic mass measurements, aiding nuclear physics and modeling.

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

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

Understanding how supernovae produce essential heavy elements for the universe.

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

Explore the Standing Accretion Shock Instability and its effects on supernovae.

Research uncovers new energy states in potassium isotope K-40, challenging existing models.

A study on the structural responses of the MAST-U tokamak under various loads.

This study investigates uncertainties in parton shower simulations and their effects on jet behavior.

Research explores how exotic molecules interact with conventional hadrons.

Research on Ru and Zr collisions reveals insights into nuclear properties and particle behavior.

Learn how AT-TPCs track low-energy particles in nuclear physics.

Research investigates how electron spins affect helium-4 scattering results.

Studying actinide signals from neutron star mergers for heavy element origins.

A look into how photons reveal insights about heavy ion collisions and quark-gluon plasma.

New insights into neutrino interactions reveal key aspects of pion production.

A look into nucleons, their structure, and the role of mesons.

Research reveals insights into gluon distributions within hadrons through advanced methods.

Research aims to clarify nuclear matter behavior using heavy-ion collision data.

Learn the basics of particle interactions through scattering theory.

Research highlights magnetic dipole transitions affecting gamma spectra in nuclear collisions.

Research on muonic atoms sheds light on energy levels and fundamental properties of matter.

Researchers use machine learning to enhance predictions of infinite nuclear matter efficiently.

A look into the lesser-known processes in nuclear physics.

Investigating local currents in varying magnetic fields during heavy-ion collisions.

Research on heavy ions reveals valuable insights into nuclear structure and matter behavior.

Transversity offers insights into hadron structure and quark contributions.

New study integrates three-body forces to improve understanding of light hypernuclei.

Studying elliptic flow reveals insights into quark-gluon plasma behavior.

Explore the complex nature and implications of neutron stars and antikaon condensation.

NA61/SHINE explores particle interactions, revealing new findings about charm quarks and kaon production.

Researchers enhance our understanding of element formation during stellar explosions.

Research sheds light on charge behavior in heavy-ion collisions and Quark Gluon Plasma.