Latest Articles for Experimental Research

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

This article explores the significance of heavy quarkonia in particle physics.

Research highlights chiral superfluidity's behavior in confined helium-3 films.

This study explores how charged particles interact during high-energy collisions.

Research reveals key patterns in baryon and anti-baryon behavior during high-energy collisions.

Exploring charmonium decays reveals key information about particle interactions.

This study focuses on detecting long-lived particles to uncover new physics.

A new thermal spectrometer offers a simpler way to measure superconducting circuits.

A look into the behavior of Bose gases at low temperatures.

Research explores how exotic molecules interact with conventional hadrons.

A new model offers insights into neutrinos and lepton behavior.

A look at the X(3872) and its connection to meson interactions.

Scientists study black holes with ultracold atoms, revealing insights into quantum mechanics.

Scientists use the KrkNLO method for precise predictions in particle collisions.

Exploring the unique properties and behaviors of strange metals in electrical conduction.

This article explores the significance of -boson pair production in particle physics.

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

Enhancing energy measurement precision in particle physics experiments.

Amorphous solids can remember their deformation history and adapt to stress.

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

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

Exploring the significance of lepton-flavor violation in particle physics.

Unraveling the mysteries of one-dimensional gases through density correlations.

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

A method to assess entanglement using the Wigner function in quantum systems.

Researchers manipulate light direction using atomic motion and topological models for new optical devices.

Gradient flow renormalisation improves calculations for meson properties and lifetimes.

This study reveals how proton bunches change in plasma and how we measure them.

Transversity offers insights into hadron structure and quark contributions.

Insights into how granular materials react to stress near unjamming.

Research on charged particles from proton-proton and lead-lead collisions reveals new insights.

This article explores how fixed particles affect the dynamics of glass-forming materials.

Researchers explore diamond's potential in detecting elusive low-mass dark matter.

Exploring superconductivity in triangular lattices using the Hubbard model reveals new states and properties.

Research aims to uncover possible light scalar particles alongside the Higgs boson.

New research highlights complexities in measuring neutrino mixing angles due to Lorentz invariance violation.

Researching muon neutrinos and anti-neutrinos to refine particle physics models.

Scientists study dark photons through high-energy particle collisions for clues about dark matter.

Study of neutrinos sheds light on fundamental forces and potential new physics.

Exploring flat bands and their potential in cutting-edge technologies.