Physics - Mesoscale and Nanoscale Physics

Exploring new waveguide designs to reduce energy loss in phononic systems.

Researchers develop a method to control spin waves with light for faster technology.

Research reveals unique properties of twisted bilayer graphene and its potential applications.

This article examines the unique features of driven systems and their topological characteristics.

A new technique generates squeezed light using excitons and phonons at room temperature.

Skyrmions are stable magnetic structures that offer potential for advanced technologies.

Researchers expand motion states of massive particles, revealing new insights into quantum mechanics.

New method streamlines analysis of particle movement in quantum systems.

Study explores spin current dynamics in metal-altermagnet interfaces.

A look at the Hall effect and its significance in organic semiconductors.

New magnetic nanoparticles could enhance cancer therapy effectiveness and safety.

Exploring how strain effects in SWCNTs can transform electronic devices.

hBN spin defects enhance precision in quantum sensing across multiple fields.

Exploring the phases and electron interactions in ABC graphene and their role in superconductivity.

This study explores superconductivity and magnetic properties in rhombohedral trilayer graphene.

Exploring the links between van Hove singularities and exceptional points in physics.

An overview of current-induced circular dichroism and its implications in materials science.

Explore the unique phases and properties of graphene under strong magnetic fields.

Investigating spin waves may transform data transmission in future technologies.

Research reveals innovative control of light using electric fields in CrGeTe.

Examining the properties of CdHgTe and the effects of Kane fermions under terahertz radiation.

Examining how impurities affect the conductivity of transition metal dichalcogenides.

A look into how magnets affect chiral spin-triplet superconductors.

This article explores chirality and its implications in gapped phases of matter.

ZGNRs show promise for improving energy harvesting and cooling technologies.

Study reveals how disorder affects unique electrical properties of special materials.

Research reveals how specific ions can improve perovskite solar panel efficiency.

This study examines multifractal statistics in non-Hermitian systems utilizing Cayley trees.

Learn how active steering manages qubit states amid noise and errors.

Research reveals how in-plane magnetic fields influence the conductive state of bilayer graphene.

Research reveals surprising changes in electrical behavior of pentalayer graphene.

New developments improve electronic properties for quantum technology applications.

Exploring how magnetism influences current flow in twisted Weyl semimetals.

This article explores the interplay between superconductors and antiferromagnets through N eel triplet correlations.

Study reveals the importance of longer-range interactions in graphene's unique phases.

A novel technique improves the study of NV centers for quantum applications.

Exploring the impact of magnetic impurities on superconducting properties through YSR states.

Research reveals how surface changes in CaP affect magnetic properties.

Research reveals novel polariton behavior in perovskite double microcavities with potential applications.

Research integrates valley physics with quantum systems for better electronics.