Latest Articles for Laser Technology

New models enhance predictions for high-intensity laser experiments in quantum physics.

Researchers manipulate light waves using four-wave mixing in rubidium for new insights.

Study reveals methods for analyzing fast electron bunches using transition radiation.

A look at how laser waves interact with materials through the bi-laplacian Schrödinger equation.

New techniques promise high-energy particle acceleration using laser wakefield methods.

Understanding weak coherent pulses is key to enhancing quantum communication security.

A flexible device improves timing measurement of ultrashort laser pulses across various fields.

A novel technique to cool hydroxyl ions opens doors to scientific advancements.

A new design enhances efficiency in measuring extreme ultraviolet light.

Exploring how light interacts with matter to create high-frequency radiation.

Tunable lasers play a key role in medical, communication, and chemical applications.

An overview of terahertz radiation produced by laser interactions with materials.

A novel laser technology that advances light manipulation and applications.

Exploring the behavior of charged particles in strong electromagnetic fields and their equilibrium.

Research reveals how atoms behave in dissipative optical lattices with Brillouin modes.

Researchers achieve progress in preparing molecular ions for precise experiments.

Research advances understanding of zinc isotopes using laser-induced fluorescence techniques.

Researchers investigate cesium atoms in Rydberg states using advanced spectroscopy techniques.

Research explores mode-locking without traditional absorbers using microresonators.

MECSELs offer tunable, cost-effective lasers for diverse applications.

New measurements improve Yb ions for precise frequency standards.

New model improves accuracy and efficiency predictions for erbium-doped fiber lasers.

Researchers study high-harmonic generation in ReS2 for future technology applications.

Examining high-harmonic generation to reveal material behaviors and applications.

New laser-driven techniques offer insights into cell responses to high radiation doses.

Research on plasma light emission boosts particle accelerator technology.

A new method improves laser field accuracy in high-intensity applications.

A study on low-noise frequency combs with enhanced pulse energy for precision spectroscopy.

New design offers efficient small lasers using quantum dots for communication and sensing.

Investigating collisional absorption's role in the Raman gap observed in laser-plasma experiments.

New analyzer improves TR-ARPES for studying material dynamics.

A new gas target design boosts electron beam quality for laser-plasma accelerators.

The FEBE beam line at CLARA will support advanced research with high-energy electron beams.

A new method enhances precision in measuring quantum states using ultracold atoms.

A new laser amplifier design offers high energy and stability for various applications.

Examining how laser pulses influence magnetism and domain wall behavior.

Examining how circular dichroism affects electron scattering in hydrogen atoms.

XFELs harness high-energy gamma rays for groundbreaking particle physics studies.

Scientists explore the unique properties of alkaline-earth ions for precision measurements.

Aluminum chloride (AlCl) shows potential for laser cooling in advanced physics studies.