Latest Articles for Experimental Science

CERN's ALICE experiment enhances particle tracking with new sensor technology.

Analyzing interactions of an exotic neutral vector boson in particle physics.

Enhancing molecular behavior predictions through improved potential energy surfaces.

Investigating how gravity influences quantum entanglement and particle behavior.

Researchers investigate neutrinos' properties using dark matter detection experiments.

An overview of unpredictable behavior in interacting quantum systems.

Learn how power corrections improve accuracy in particle collision predictions.

Scientists investigate phase changes in matter using particle collisions at CERN.

Research reveals complex behaviors of neutral plasma with long-range interactions.

An overview of wave-particle duality and its implications in quantum physics.

Scientists investigate axion dark matter and its impact on the quantum Hall effect.

This article examines the complex behavior of magnetic pendulums influenced by magnetic fields.

New experiments aim to uncover details about neutrinos and fundamental forces.

This paper presents a fresh approach to analyzing neutrino interactions using superscaling.

Researchers study how oscillating mass may affect the equivalence principle and dark matter interactions.

A new method improves atom array setups for quantum computing.

Study examines how noise and signals impact Rydberg atoms' collective jumps.

Investigating the elusive nature and decay of neutrinos from cosmic sources.

Scientists explore dark matter's existence via innovative detector technology.

ATLAS Collaboration provides new limits on SUSY particles and dark matter implications.

Investigating dark matter interactions using nuclear reactors offers new research opportunities.

Investigating ultralight dark matter and its explosive phenomena can reveal cosmic secrets.

Scientists are enhancing quantum state transfer methods to improve information processing.

LZ experiment searches for elusive particles beyond WIMPs.

Investigating elusive particles that may answer fundamental questions about our universe.

A new model simulates growth and movement of epithelial cells in tissues.

Research on maintaining entanglement in quantum systems disrupted by noise.

Cells navigate surfaces based on firmness, affecting healing and tissue development.

Scientists develop a method to find Hamiltonians through innovative measurements.

Researchers achieve new insights in quantum simulation using optical cavities and collective spin models.

Research focuses on charmonium production via photon and Odderon interactions.

Investigating hybrid mesons could reshape our knowledge of particle interactions.

Investigating critical points in quantum chromodynamics and their significance in understanding matter.

A novel method helps measure dark matter movement uncertainties for better detection.

Exploring the detection and interaction of dark matter particles with atomic nuclei.

Researchers analyze top quark and photon interactions for insights into particle physics.

A look into causal relationships in quantum experiments and their implications for theories.

A new software approach helps reduce radon noise in dark matter detection.

A new method improves calculations in particle physics, especially for fragmentation functions.

Research shows how machine learning enhances droplet size measurement techniques.