Latest Articles for Optics

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

This article covers key aspects of laser physics and its various applications.

This article explores new methods for measuring distances between photons with high precision.

This article presents an efficient way to calculate how materials absorb light.

This article explores how light momentum behaves in various natural light situations.

Examining how giant fullerenes can enhance high-order harmonic generation.

New methods improve wave scattering analysis in various fields, enhancing technology and science.

A new framework combines machine learning with lens design for better light control.

Researchers develop new methods to control light using glided photonic crystal interfaces.

Charge Density Waves reveal new possibilities in material behavior under electric currents.

Study reveals effects of quantum coins and disorder on rogue amplitudes.

New methods enhance precision in measuring angular velocity through weak values and recycling techniques.

A detailed look at phase measurement algorithms and their challenges.

Researchers improve time measurement precision through photon state manipulation.

New technology aims to improve observations of cosmic events using Laue lenses.

Learn quantum optics basics and perform calculations using MATLAB.

Discover how exceptional points enhance sensing technologies using spherical resonators.

This article examines new techniques for simulating light in particle physics.

This article examines integrable systems through the lens of Lax operators and their equations.

A look into wave stability and instabilities in various contexts.

Discover how strong light modifies the electronic properties of materials.

Researchers propose a novel technique to enhance structured light applications.

New method improves wavefront sensing in telescopes.

Research reveals how vortex beams change upon reflection.

Exploring the unique properties and applications of 2D materials in various fields.

A look into optical levitation and its potential through nonlinear feedback forces.

Exciton-polariton condensates may lead to new all-optical technologies and efficient devices.

Exploring the behavior of surface plasmon-polaritons in graphene with gain and loss.

Erbium ions in cerium oxide show promise for enhancing quantum communication systems.

Exploring the potential of polariton states in thin materials for technology.

Super-thermal light offers promising improvements in imaging techniques for sensitive samples.

A new cavity approach allows open access while achieving strong coupling with molecules.

Innovative methods improve the design and manufacturing of optical devices.

Examining new insights into atomic interactions using nonlinear sub-Doppler techniques.

RIGID uses machine learning for efficient metamaterial design with minimal data.

Research shows optical cavities can change chemical reaction behavior for improved efficiency.

Exploring unique states of light through strong laser interactions with materials.

Microcavities reveal unique light behaviors, impacting technology in significant ways.

Research focuses on converting microwave and optical signals using rare-earth-doped crystals.

Using machine learning to improve optical tweezers for precise particle rearrangement.