Latest Articles for Photonics

A look into controlling supercontinuum light using dual-core waveguides.

New methods improve the purity and control of photon pairs for quantum applications.

Investigating programmable photonics for studying topological systems and light behavior.

Exploring new laser technologies using topological insulators and Landau levels.

Bilayer graphene shows promise for generating currents from light with applied voltage.

This method improves photonic designs by integrating real-world data with machine learning.

New photonic chip technology generates compact, low-noise microwave signals for various applications.

Research reveals efficient methods for preparing high-dimensional frequency entangled qudits in quantum technology.

New frameworks enhance the understanding of nonlinear topological materials and their applications.

Research on partially spatially coherent qubits enhances secure quantum communication methods.

Time telescopes improve information transmission in quantum networks, enhancing communication capabilities.

Discover how nanowires are shaping quantum technology through emission and detection innovations.

Research reveals how stacking affects light emission in hexagonal boron nitride.

Examining how photons and phonons influence qubit transitions in quantum setups.

New optical coding methods improve image transmission and clarity.

Researchers use light to influence phonon behavior in graphene, enhancing its properties.

A new device improves light conversion for quantum networks.

Exploring the behavior of electromagnetic waves in changing materials and its implications.

Recent studies reveal the potential of solitons in dynamic waveguide systems.

Study of light's behavior in quantum systems and its tech potential.

Exploring the potential and challenges of optical neural networks using light for computation.

Zinc-treated nanocrystals improve stability and efficiency for single-photon sources.

New methods improve efficiency in second harmonic generation for optical devices.

Transmitting entangled photons through hollow-core fibers marks a key advancement in quantum communication.

Exploring advances in microwave technology through kinetic inductance nanowires.

Researchers examine how accelerated light influences photon entanglement in quantum physics.

Exploring the fascinating interactions of plasmons in graphene and their potential applications.

Discover how excitons influence the future of electronic and optical devices.

Researchers develop a method to improve photon pair generation in nonlinear optics.

New cavity polaritons offer improved stability and potential for quantum applications.

New materials enhance control over light in optical technologies.

This study reveals how CO2 position on gold alters charge injection energies.

Researchers work to enhance light interactions using gain materials in metal cavities.

New methods for generating entangled photon states pave the way for quantum technologies.

A new method enables easier detection of light superpositions using a single photon detector.

This research examines polariton condensates and their behavior in magnetic fields.

Research highlights the potential of hBN for quantum state generation.

Research reveals how circularly polarized light impacts electron dynamics in materials.

A look at how a microwave photon detector operates and its measurement techniques.

Researchers enhance light emission through tuning organic molecules for quantum applications.