Physics - Mesoscale and Nanoscale Physics

Researchers enhance PCM performance using computer algorithms for better light management.

This study focuses on developing models for topological insulator materials.

Researchers improve resonator efficiency with single-crystal silicon carbide, reducing energy loss.

Study reveals unique magnetic behaviors in chromium trihalides, impacting future technology.

Exploring the connection between Majorana states and quantum dots for future technology.

Twisted multilayer graphene displays unique electronic properties, enabling future technologies.

Examining how electric and magnetic waveguides affect electron behavior in graphene.

This article explores the connections between semiclassical and response theories in electric fields.

Polarization textures in 2D materials could reshape technology and electronics.

Exploring the interplay of magnetic topological insulators and superconductors for future technology.

A look into the electronic behavior of twisted bilayer graphene and its significance.

Two-dimensional materials are reshaping device technology with their unique properties.

Researchers develop a device to study edge magnetoplasmon waves and anyonic properties.

A deep dive into how current affects topological superconductors and Weyl semimetals.

Discover the unique superconducting properties of rhombohedral trilayer graphene.

Creating room-temperature chiral magnets opens new possibilities in signal processing and data storage.

Discover how superwires guide electrons and their potential in technology.

A study on how impurities act in various models when excited.

Examining the role of charge dynamics in enhancing quantum dot performance.

Quantum dots are small particles with unique properties, impacting various fields.

Researchers study plasmonic crystals for advanced sensing and electronic applications.

Modular spin-circuits merge physics and technology for advanced computing solutions.

Cylindrical magnetic nanowires show promise for future data storage and processing technologies.

A fresh measurement method offers a better understanding of memory effects in quantum systems.

Scientists leverage machine learning to optimize Kitaev chains for Majorana state discovery.

Research on HgTe reveals unique electron interactions and their effects on conductivity.

Discover how sliding layers of atoms influence electrical properties.

Research on germanium-based quantum dots enhances quantum computing capabilities.

This article examines fractional quantum Hall states and their implications.

Research reveals new findings on spin currents in ferromagnetic films.

Examining the electrical properties of topological insulator nanowires under magnetic fields.

Examining unique properties and behaviors of topological phases in materials.

New method allows precise control of quantum behaviors using machine learning.

Researchers use magnetic fields to improve heat management in tiny devices.

Researchers unveil T-MoTe's potential in quantum computing through unique superconducting states.

Researchers explore InP/GaSb nanowires for stable quantum computing applications.

Research on tunable materials enhances the study of Berry physics and its applications.

Researchers are advancing methods to control ferrimagnetic skyrmions for future tech.

A look at how energy gap law influences molecular behavior and light emission.

Investigating the formation and stability of fractional Chern insulators in novel materials.