Physics - Mesoscale and Nanoscale Physics

New nanorobotic actuators leverage 2D materials for precise movement and functions.

An overview of tunneling magnetoresistance in magnetic junctions and its technological implications.

Examining how electrostatic patches affect scientific measurements across various experiments.

A deep dive into fractional quantum Hall states and their implications for technology.

This study examines the Geometric Binder Cumulant for analyzing polarization in materials.

New nano-antennas utilize unique materials for effective and compact radio wave transmission.

This study examines heat transfer between materials through phonons and their interactions.

Research on InAs/GaSb nanowires reveals new possibilities in electronics.

Investigating the unique properties and applications of gapped graphene in technology.

Research reveals how carbon nanotubes can create stable self-locking structures.

Recent study reveals important properties of doped graphene leads for future electronics.

Research on higher-order Dirac and Weyl semimetals reveals new properties.

New methods enhance understanding of phonon interactions with lattice defects in materials.

Study reveals how oxygen groups on graphene enhance heat transfer with water.

Aluminum nitride shows promise for efficient light-emitting devices.

Study reveals how randomness affects magnetoresistance in graphene under magnetic fields.

Researchers study wave behavior with synthetic dimensions using microwave resonators.

Skyrmions could transform electronic data storage with their unique properties.

Merons influence skyrmion behavior and phase transitions in magnetic materials.

Recent studies uncover unique wave properties in non-Hermitian systems, revealing practical applications.

Study reveals interactions between Majorana states and electron transport in quantum dots.

New DFXM model reveals dislocation structures and their impact on material behavior.

Exploring silver nanowires and their potential in electronics and computing.

Exploring the Aubry-André model and its impact on particle dynamics.

Research reveals how temperature and size affect spin dynamics in nanocrystals.

This article explores how disorder affects nodal-knot semimetals and their electronic properties.

Exploring the potential of altermagnetic superconductors in future technologies.

Exploring how new materials can transform heat management and energy systems.

Scientists study natural light harvesting to improve energy transfer technologies.

Research reveals how magnetism influences weak topological insulators and their properties.

Researchers are creating new systems using skyrmions for energy-efficient electronics.

Discover unique properties of topological materials and their potential technological impacts.

A look into the role of quantum dots in next-gen computing.

Study reveals how iron nanocluster size impacts melting points and behavior.

Researchers create a new quantum device using superfluid helium for potential breakthroughs.

New method aims to enhance magneto-conductance patterns in quantum wires.

Research highlights advancements in using electric fields for controlling quantum spins.

Study reveals strong coupling methods for magnon and photon interactions over distances.

Exploring competing interactions and phases in thermodynamic systems.

Examining energy movement through a Bethe lattice model with sources and drains.