Physics - Atomic Physics

Researching how magnetic fields affect coherence in rare-earth ions for quantum information.

YbOH helps scientists investigate the electron electric dipole moment for new physics insights.

New laser technology enhances the excitation of Rydberg atoms for quantum applications.

New techniques enhance studies of electron behavior with attosecond X-ray pulses.

This article discusses recoil-free quantum gates using optical qubits for better fidelity.

This article reviews parity violation effects in cesium, focusing on nuclear interactions.

Researchers improve accuracy of multi-ion optical clocks using a new method.

A method allows simultaneous measurement of properties in two Bose gases.

Research reveals new insights into low-temperature interactions of ArH with electrons.

New laboratory studies enhance knowledge of Fe II energy levels for astrophysics.

Research reveals new Nd III energy levels crucial for star analysis.

A new method improves the calibration of spatial light modulators for better light control.

Scientists make strides in studying Yb ions for technology and precision measurements.

Research shows carbide interlayers can enhance heat transfer in electronics.

Scientists study unique atomic groups called trimers and their interactions at low temperatures.

Examining sputtering issues in heavy-ion experiments for superheavy nuclei synthesis.

Research reveals how light affects the beryllium atom's electron behavior through photoionization.

Researchers are pushing laser technology limits using superradiance for improved stability.

An in-depth look at how relativistic effects influence atomic polarizability in main-group elements.

This article explores how heavy ions interact with Mylar in nuclear research.

Isotope shifts provide insights into nuclear properties and fundamental physics.

Researchers measure Landau-Zener Rabi oscillation in cold atoms for improved quantum technology.

Research reveals a new type of skyrmion with unique properties in superfluids.

Research focuses on improving Rydberg atom bandwidth for better communication technology.

Researchers develop slow light technology to improve laser frequency stability.

Study examines how collisions affect rubidium atoms' energy states and light emission.

Research reveals how inert gases affect Rydberg atom behavior.

New methods enhance predictions for nuclear fission processes and behaviors.

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

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

Explores light interactions with two-level atoms in non-LTE conditions.

Researchers study excited states in nitrogen ions using the Hanle effect.

A simple technique improves magnetic field measurement accuracy in three dimensions.

An overview of the control system essential for ultracold atom experiments.

Research on hydrogen atoms under strong magnetic fields reveals important quantum behaviors.

Research reveals insights into magnetization oscillations affected by a rotating magnetic field.

Rydberg atom sensors offer a promising solution for detecting weak radio frequency signals.

Research reveals significant insights into RaF's ionization potential and molecular properties.

Research reveals how gravity affects atomic clocks and quantum systems.

Exploring key concepts and implications of the Stern-Gerlach experiment in quantum physics.