Physics - Mesoscale and Nanoscale Physics

Research reveals new insights into fractional Chern insulators in layered graphene structures.

Exploring the connection between fractal lattices and topological insulators.

Investigating how rhombohedral graphene's unique properties impact technology and science.

Studying gravitational waves could reveal significant cosmic events and mysteries.

Research reveals exciting interactions between magnons, phonons, and light for future technologies.

This article examines how strain influences the electronic behavior of ZrSiS.

Study reveals insights into CrSBr's spin textures for advanced electronics.

Research reveals interesting light interactions in moiré superlattices for electronic applications.

This article examines how spin polarization can be analyzed in Anderson impurities.

ELEQTRONeX enhances understanding of non-equilibrium transport in nanomaterials.

A study on electron spin properties in EuZn Sb enhances material knowledge.

Researchers develop a technique to measure electron states in topological chains.

Research unveils key factors influencing single-photon emission in quantum technologies.

This study explores how impurities affect localized states in flat band systems.

Study reveals how curved graphite responds to magnetic fields.

A look into how domain walls form in materials under ultrafast conditions.

Studying the unique properties of anyons in quantum Hall systems.

A look at anyons and their implications in quantum physics.

Researchers modify YBCO films using helium ions to improve superconducting properties.

New method boosts superconducting nanowire detectors' performance for single photon detection.

Examining the effects of quantum coherence on current fluctuations in open quantum systems.

This article discusses how edge roughness affects the performance of two-dimensional materials.

New devices enhance signal amplification for quantum computing and communication.

MoTe's unique properties offer new possibilities in optics and electronics.

Study reveals insights into heat and electricity movement in 2D materials.

Study reveals how metal additions enhance connections in electronic materials.

Exploring how quasinormal modes reveal black hole behaviors and interactions.

New methods improve control of silicon spin qubits at low temperatures, enhancing quantum computing potential.

Research reveals efficient polarization switching in two-dimensional sliding ferroelectrics.

Explore how honeycomb antiferromagnets and magnons could transform technology.

Research reveals fascinating interactions between excitons and phonons in layered materials.

STIRAP enhances precision in quantum sensing using nitrogen-vacancy centers in diamonds.

Research shows how mechanical strain alters graphene's electronic characteristics.

Research reveals how thermal treatments affect YIG's Gilbert damping and potential applications in spintronics.

Nanomagnets mimic neuron functions to improve computing efficiency and adaptability.

A new diamond sensor offers precise magnetic field measurement in various settings.

Innovative backgate integration enhances germanium-based quantum devices.

Research on interlayer excitons reveals new opportunities in electronics and optics.

Researchers achieve precise control over quantum dots in nanowires, aiding quantum computing efforts.

Research reveals promising properties of RTO nanocrystals for advanced memory devices.