Physics - Mesoscale and Nanoscale Physics

Study of gold and silver atomic contacts under magnetic influence.

Hybrid metal-semiconductor devices reveal complex electron behaviors under varying conditions.

Discover how memristive technology can transform matrix inversion efficiency.

Discover the unique electronic properties of supertopological materials and their potential applications.

A new spectrometer makes ESR accessible and customizable for researchers.

Research shows how environments can enhance energy transport in quantum systems.

Control magnons with electric fields in multiferroic materials like NiI.

Examining how temperature influences electron and hole behavior in CsPbI nanocrystals.

Research on ferromagnets and superconductors could lead to advanced technology.

Exploring the role of organic polariton systems in optical computing technologies.

Colloidal semiconductor nanoplatelets show promise for efficient single-photon emission.

Research reveals new methods for controlling silicon-based qubits and addressing crosstalk challenges.

Exploring the unique properties of twisted-bilayer lattices in Bose-Einstein condensates.

Examining the unique properties of quasiparticles and their fractional statistics.

Research focuses on improving electrical contacts to enhance quantum computing.

Research reveals unique electron behaviors in twisted bilayer graphene's moiré patterns.

Examining connections between acceleration and particle behavior in quantum physics.

This article examines projected Fermi sea states and their physical properties through tensor networks.

Research reveals behavior of electrical and thermal properties in 2D topological materials.

Researchers study the charge behavior of CuPc on NaCl layers using STM.

Investigating the Blatter radical's role in electronic devices and its magnetic properties.

Exploring how fractional calculus enhances the modeling of physical phenomena.

Exploring high-frequency spin waves in antiferromagnetic materials for advanced data processing.

Explore polaron formation in various insulating materials and its implications.

Researchers enhance heat transfer efficiency using magneto-optical nanoemitters and magnetic fields.

Research reveals unique light interactions with twisted materials, opening new optical applications.

Exploring how impurities affect unique behaviors in non-Hermitian systems.

New hybrid structures enhance control over spin waves for innovative technology applications.

New techniques improve single photon emitters for quantum technology applications.

This study investigates how heat moves in Mott insulators, focusing on spins and phonons.

Recent research sheds light on electron movement in quantum dot arrays.

Research reveals how electric and magnetic fields affect quantum materials.

Research tackles phonon-induced errors in spin qubits for better quantum computing.

Researchers investigate the unique behavior of odd-even effects in neutral atomic quantum gases.

Explore the potential of quantum batteries and local ergotropy in energy extraction.

Exploring the transition between fluid-like and structured electron states in two-dimensional materials.

New insights on antiferromagnets with charge-density waves and their unique electrical properties.

New spintronic technology enhances time-series data processing efficiency and accuracy.

New research shows carbon nanoscrolls can greatly enhance electrical conductance under magnetic influence.

Chiral gold nanocrystals reveal unique electrical properties influenced by magnetic fields.