Physics - Mesoscale and Nanoscale Physics

Study reveals how thickness and substrate affect NbTi superconducting performance.

Research reveals the graphene-water interface is acidic, impacting ion behavior.

Research shows how wave function geometry improves thermoelectric materials' performance.

A look into how decoherence affects quantum systems and their symmetries.

Research reveals how light influences the unique properties of topological semimetals.

Patterned dielectric superlattices reshape graphene's electronic properties for future technologies.

Research investigates superconductivity potential in heavily-doped single-layer graphene.

Investigating the impact of twist angles on the electronic properties of graphene layers.

Study of how electric currents affect electron spins in various materials.

Researchers reveal hidden curved spaces in the bosonic Kitaev model, impacting quantum behavior.

This study examines how temperature affects the movement of gold nanoparticles.

Exploring the formation and potential of Meron Kekulé lattices in technology.

Research shows how microwave signals can stabilize magnetic oscillators for better performance.

Exploring quantum geometry's role in one-dimensional periodically driven systems.

Exploring synthetic frequency dimensions to control magnons for enhanced information processing.

Research reveals unique properties of graphene quasicrystals and their potential in superconductivity.

New methods improve understanding of particle and energy movement in complex systems.

Study reveals the role of Coulomb scattering in ballistic photocurrents and their potential benefits.

Learn about the unique properties and significance of topological states in structures.

A novel gate layout improves valley-polarized current generation in two-dimensional materials.

Exploring the complex interactions between fractional quantum Hall states and fractional Chern insulators.

Learn how laser light influences electrical behavior in graphene materials.

Strategies to improve data accuracy in Magnetic Resonance Force Microscopy.

Research reveals unique properties of zigzag-edged CrN nanoribbons for future technologies.

This paper discusses how electrons emit light and change momentum in electromagnetic fields.

Research reveals how spins and magnetic fields influence skin effects.

New techniques improve control of spin-qubits using single-atom magnets.

A study on using microwave spectroscopy to examine Andreev bound states in semiconductor junctions.

Research reveals new methods for creating oxide nanoscrolls with potential applications.

Examining spin relaxation and diffusion in monolayer 1T'-WTe for advanced electronics.

Exploring the Casimir effect and its implications across various particle systems.

Research reveals how particle density affects movement patterns in fluid systems.

New algorithms enhance understanding of surface states in photonic and acoustic systems.

The SHNA uses the spin Hall effect to emit electromagnetic waves efficiently.

Research on multiterminal Josephson junctions reveals unique properties of superconductors and normal metals.

A look into the innovative altermagnetic material 2D-CRO and its potential uses.

Scientists reveal how light induces fast state changes in materials.

New method enhances accuracy in placing tiny gold droplets for material studies.

Exploring the effects of non-Hermiticity in twisted bilayer graphene's electronic properties.

A fresh approach to understanding charge dynamics in batteries and electronics.