Latest Articles for Experimental Science

Researchers enhance entanglement stability in large systems through optimal feedback control methods.

Scientists investigate vector-like top quarks to address fundamental mysteries of the universe.

Investigating right-handed neutrinos could change our understanding of particle physics.

This article discusses a new approach to producing polarized electron beams using a double-layer target.

A new technique generates squeezed light using excitons and phonons at room temperature.

Research sheds light on matter behavior in extreme conditions through net-charge fluctuations.

Scientists are pushing the boundaries of quantum physics with levitated masses and superposition states.

A new atomic oven design optimizes efficiency for quantum technology applications.

Study reveals how electric fields slow superradiant light emission in ultracold Rydberg atoms.

Exploring vacuum decay and its implications for the universe.

Research reveals how gravity affects atomic clocks and quantum systems.

Discover the techniques improving our ability to detect gravitational waves.

Examining turbulence behavior in Bose-Einstein Condensates and its implications.

Rydberg atoms show promise for advancements in quantum information science and technology.

Research focuses on scalar bosons and their potential role in understanding new forces.

New method improves fluid flow modeling with limited and noisy measurements.

Examining the role of photons in particle collisions at high energies.

A new approach to testing the connections between gravity and quantum mechanics.

Researchers investigate elusive particles that may reveal new physics through neutrino interactions.

Research reveals a unique shock in laser-created plasmas, offering insight into space phenomena.

Exploring how defects in optical lattices affect quantum correlations.

Examining how electroweak phase transitions influence gravitational waves and the universe's evolution.

This study investigates how photons excite atoms and the implications of group delay.

A look into jet quenching phenomena in quark-gluon plasma.

Examining light nuclei helps reveal essential insights into extreme matter behavior.

Scientists explore neutron detection for dark matter insights.

This article discusses the challenges of detecting gravitons in strong gravitational fields.

Researchers pursue a potential new particle that may explain dark matter.

Examining how moving detectors reveal insights into quantum gravity and spacetime.

Research sheds light on chromium-46's unique properties and behavior.

Scientists aim to find elusive millicharged particles using the Super Tau Charm Facility.

Exploring the impact of observation on quantum particles through innovative experiments.

A deep dive into nucleons, resonances, and their properties.

Investigating dark particles through proton collisions offers insights into dark matter.

XENONnT aims to uncover the secrets of dark matter using advanced detection techniques.

DUNE aims to deepen our knowledge of neutrinos and their intriguing properties.

Scientists propose a unique method to study dark matter interactions using different-sized test bodies.

NA64 experiment at CERN seeks clues about Dark Matter's hidden interactions.

Neutrinos have mass, raising questions and opening new avenues for research.

Researchers use machine learning to uncover insights about axions and flavor symmetry.