Physics - Mesoscale and Nanoscale Physics

Explore the fascinating properties of massless fermions and their interaction with magnetic fields.

New methods reveal insights into topological materials through microwave light interactions.

Research reveals new properties of zigzag Haldane nanoribbons and their unique topological states.

A study on dislocation skin effects and topological properties in non-Hermitian materials.

Study of light's behavior in quantum systems and its tech potential.

Discover unique properties of lattices influenced by imaginary magnetic fields.

Scientists investigate axions and their detection using sensitive Josephson junctions.

Exploring the nuances of quantum sensing and its applications in particle detection.

Exploring Majorana bound states' potential in quantum computing and superconductivity.

Study reveals stability and electronic features of CPA monolayers with potential applications.

This study highlights how angular momentum influences light-matter interactions in chiral cavities.

Researchers enhance quantum computing through improved signal readout technologies.

Exploring the role of Raman spectroscopy in studying Platinum Diselenide layers.

New findings on interface excitons offer insight into optoelectronics and quantum technologies.

Researchers improve nanoacoustic devices with new mesoporous materials for better environmental sensing.

Research advances in simulating spin chains using quantum computers.

Researchers investigate spin torque oscillators for energy-efficient computing technologies.

Zinc-treated nanocrystals improve stability and efficiency for single-photon sources.

A look into charge-spin conversion and its significance in electronic devices.

Research on graphite nanoribbons reveals potential for innovative light polarization applications.

New larger resonators improve performance in sensing applications.

Research shows how altering interactions can stabilize particle systems under various conditions.

Exploring quantum dots and their impact on electronic technology.

Researchers reveal stable configurations of merons in twisted magnetic materials.

A new quantum current sensor improves accuracy in measuring electrical currents.

New multimode optomechanical systems enhance interaction between light and mechanics for advanced applications.

A look into unique properties of non-Hermitian systems and their implications.

Exploring the interaction between superconductors and magnets for future technologies.

Researchers develop methods to clarify electrical signals in magnetic topological insulators.

Research focuses on spin decoherence in VOPc@GNR systems for quantum computing advancements.

Research shows machine learning can classify spectral densities in quantum systems effectively.

Research reveals complex behaviors of electrons and holes in layered materials.

Discover the quirky behaviors of non-Hermitian systems and their impacts.

The new mon qubit design enhances quantum computing efficiency and reliability.

Flowermon qubits promise improved performance and reliability in quantum computing.

Exploring the electronic properties of twisted bilayer graphene and its unique phases.

Research reveals new magnetic phases in nickel dihalides, including skyrmions and biskyrmions.

Recent studies show light can change material magnetic properties via spin-phonon coupling.

Lattice DFT enhances understanding of complex electronic systems and interactions.

Research reveals how magnetic states affect conductance in MnBi2Te4 material.