Latest Articles for Nuclear Physics

Recent findings in neutrino physics may reshape our understanding of the universe.

Research reveals distinct shape behaviors in Mo and Ru isotopes.

A look into the stability of hybrid stars and the effects of phase transitions.

Learn how jet energy loss reveals secrets about quark-gluon plasma.

Studying elemental abundances in metal-poor stars reveals insights into star formation.

Exploring fission behaviors and trends in Fermium isotopes.

New insights reveal unexpected behaviors in cadmium isotopes' nuclear structure.

A look into the significance and applications of pseudospin symmetry in atomic nuclei.

Investigating the transformation of nuclear matter and quark matter in neutron stars.

New imaging techniques shed light on quantum behaviors in nuclear particle interactions.

Exploring the dynamics of nuclear collisions and their impact on matter behavior.

Researchers improve predictions for heavy quarkonium production in particle collisions.

Exploring how past events shape the fission process in atomic nuclei.

Exploring the role of machine learning in understanding neutron star matter.

New mass measurements improve understanding of heavy element formation in cosmic events.

A new method for measuring photonuclear reactions using an electron accelerator.

Studying neutron stars reveals insights into their extreme conditions and internal structures.

An overview of how temperature influences nuclear matter properties and phase transitions.

New research focuses on neutrinoless double beta decay and neutrino mass models.

This article reviews a method to study fission dynamics through pairing correlations.

Study investigates effects of the X17 boson on neutron and quark stars.

Researchers study neutron density fluctuations in heavy-ion collisions to understand matter's fundamental nature.

Studying strange quark matter sheds light on extreme conditions in compact stars.

Study of interactions between light nuclei and conditions for stability.

Research unveils new excited states in pentaquarks, challenging existing particle physics models.

Examining the dynamics of heavy-ion fusion and its implications for energy and nuclear physics.

Exploring key factors in compound nucleus formation during heavy-ion collisions.

Examining different models of nucleon interactions enhances understanding of nuclear physics.

Rhenium decay offers insights into the elusive mass of neutrinos.

Examining how particle charge affects nuclear beta decay interactions.

Innovations in positron beam generation and management pave the way for scientific progress.

Examining key processes in nuclear physics through superallowed beta decays and their significance.

Understanding nuclear mass reveals insights into atomic nuclei behavior and stability.

Study of neutron interactions reveals crucial insights about nuclear forces and stability.

Recent studies improve understanding of nucleon interactions and the Standard Model.

Study reveals lower neutron production in ionized vanadium than expected.

Research reveals how light nuclei form in extreme conditions of heavy ion collisions.

Ar42's impact on experiments analyzing dark matter and neutrinos.

Research on heavy-ion collisions reveals significant insights into particle dynamics and quark-gluon plasma.

New insights into nucleon structure from parton distribution functions and lattice QCD calculations.