Latest Articles for Nuclear Physics

Explore new findings on how particles form stable states in nuclear physics.

Exploring how heavy elements spread throughout galaxies and influence their chemical composition.

An overview of projectile fragmentation reactions and invariant-mass spectroscopy.

This study examines quark confinement and chiral symmetry in nuclear matter.

This study examines beta decay of bare atoms in stellar environments.

Researchers use T-ERDA to analyze deuterium ratios in precious samples without damage.

Study of nuclear modification factors reveals insights into extreme matter conditions.

This article explores how neutron star mergers create heavy and superheavy elements.

This research examines heavy quarks' behavior in the quark-gluon plasma.

Uncover how heavy elements form and where to find them in nature.

Researchers investigate discrepancies in nuclear matrix elements for a rare decay process.

This article explores the importance of quantum coefficients in various physical systems.

Research enhances understanding of nuclear interactions using statistical techniques.

ANCs help us understand nuclear reactions in stars and element formation.

Borexino data reveals significant potassium geo-antineutrino flux affecting Earth's heat.

A new gas detector model enhances particle detection in nuclear processes.

Examining electron screening effects on nuclear reactions, especially in stars.

New techniques improve accuracy in nuclear property calculations using Green's function Monte Carlo method.

New T0 detector enhances timing accuracy in heavy-ion collision experiments.

Research enhances understanding of beta decay and isospin-symmetry breaking.

Research on pion-pion scattering reveals key interactions in particle physics.

Neutrinos offer insights into extreme environments and gravitational effects.

This article examines how magnetic fields affect surface tension in quark matter.

A new approach to studying bremsstrahlung in light nuclei interactions.

New libraries provide tools for complex nuclear physics calculations.

Quantum computing is transforming the study of many-nucleon systems in nuclear physics.

CUPID aims to detect rare nuclear processes to advance neutrino research.

Researchers test lithium molybdate crystals to study rare particle decay.

Discovering the formation and properties of Tantalum-180 in stars.

Research focuses on fission properties of Curium and Californium isotopes.

A look into the interactions of the hypertriton and their significance in nuclear physics.

Research reveals how atomic nuclei vibrate under energy inputs and collective behaviors.

New techniques improve centrality classification in heavy-ion collisions.

This article explores how vector mesons scatter with deuterons and their implications.

This study uses the Morse potential to examine neutron-proton scattering.

Using modern techniques to analyze and predict nuclear masses with precision.

Examining the role of neutrinos in neutron star merging events.

Investigating fusion excitation functions and challenges with low-abundance isotopes.

This article explores Symmetric Compton Scattering and its potential applications in various fields.

Research sheds light on heavy quarks' energy loss in quark-gluon plasma.