Physics - Mesoscale and Nanoscale Physics

Study reveals effects of NiO on Permalloy magnetic properties.

Research reveals unique behaviors of neodymium nanomagnets at tiny scales.

Researchers study strong coupling to reveal new material properties through light interaction.

Researchers study Weyl fermions and their behaviors on curved surfaces under gravity's influence.

New methods enhance understanding of topological properties in photonic systems.

Examining giant atoms' interactions and coherence in complex 2D environments.

Exploring the role of Majorana zero modes in the future of quantum computing.

Exploring how graphene advances terahertz applications in sensing and communications.

New insights into topological materials using advanced quantum simulations.

New methods improve quantum state preparation amid noise challenges.

Exploring the uses of topological Fano resonance for advanced sensing applications.

A study on optimizing tight-binding models for electronic properties of Janus TMDCs.

This study examines how electron spins influence conductance in a quantum system.

A look into the unique properties and potential applications of multi-gap topological insulators.

Exploring the role of antiferromagnets in quantum computing and sensing applications.

Research reveals how external forces affect the magnetism of biphenylene network carbon material.

Investigating acoustic Casimir forces and Bose-Einstein condensation in small helium samples.

This article examines how phonons affect heat transport in insulators and semi-metals.

Researchers uncover unique electron behaviors in two-dimensional Dirac materials.

This article discusses unique behaviors of electrons in Dirac materials under electric fields.

Tilted P-N junctions enhance valley polarization in graphene for better electronic devices.

Researchers study unique CSLs that could impact future quantum technologies.

Investigating electron behavior in quantum Hall bilayers under strong magnetic fields.

New insights into Josephson junctions using nanowires for quantum computing.

Exploring magnon behavior in honeycomb antiferromagnets for future technology applications.

New methods improve current density mapping from magnetic field data.

Altermagnetism offers new insights into magnetic materials with potential spintronic applications.

Research highlights the potential of doped semiconductors in enhancing nonlinear optical responses.

Exploring how electrons move in metals and its implications for technology.

A look into the workings and benefits of MRAM technology in data storage.

Spin waves could revolutionize data processing and storage efficiency.

Study reveals how magnetization direction affects the properties of Co-based shandite CoSnS.

Research enhances design of GNRs for efficient electronic circuits.

Carbon nanotube films control light emission for sensors and electronics.

SiV centers in diamonds offer potential for advanced quantum computing applications.

Recent findings reveal improved energy transfer methods using light and nanoparticles.

New memristive devices mimic brain functions, boosting AI learning efficiency.

This article examines how central-spin models exhibit time-crystalline behavior under periodic driving.

A look at the Casimir effect and its role in quantum physics.

Exploring topological phases, surface states, and their implications in modern physics.