Latest Articles for Materials Science

Study reveals how thin fluorobenzene films influence methyl iodide breakdown under light.

New method improves efficiency in simulating complex molecular interactions.

Researchers develop a fast, non-destructive method for measuring fiber properties.

Study reveals how niobium film properties influence microwave losses in superconducting circuits.

New technique measures atomic arrangement in thin films using standard lab x-ray sources.

This article explores anyons and their unique entanglement properties in quantum systems.

Research highlights the dielectric properties of amorphous Boron Nitride for electronics.

Understanding heat transport is crucial for advancing quantum technology performance.

A novel approach to locate saddle points in magnetic materials for better analysis.

MiniMol offers an efficient approach to predicting molecular properties with fewer parameters.

Study reveals how magnetic order affects electron and phonon behavior in MnBiTe.

New methods improve predictions in drug discovery and materials science.

Crystalformer efficiently predicts material properties using advanced attention mechanisms.

Examining the unique properties and transitions of quantum spin liquids in materials.

This study reveals high-readout accuracy in tin-vacancy centers for quantum networks.

A new method improves how we simulate particle interactions in materials science.

New techniques enhance our understanding of dislocation behavior in materials.

New approach reveals how AI predicts material properties transparently.

Researchers develop a method to better analyze crystal defects using Kikuchi patterns.

A look into ultraclean Andreev interferometers and their role in superconductivity.

Spintronic devices may transform computing by offering efficient power use and high speed.

Research highlights the potential of Janus MXenes in thermoelectric applications.

Research highlights fast switching and low energy use of VO memristors.

Learn how skyrmions could change the future of electronic devices.

Hydrogen influences the electronic structure and properties of vanadium-zirconium metallic glass.

Research on PbTe-based HEAs reveals insights into atomic movement and defect formation.

Learn how new techniques improve quantum simulation for complex systems.

Investigating how hairy particles change shape at liquid-liquid boundaries.

Researchers enhance ionic conductivity in sodium-ion batteries by modifying NASICON materials.

A study of spins in random networks and their interactions.

Research reveals how electric fields enhance electricity generation in MAPbI3 microcrystals.

New datasets and machine learning techniques enhance understanding of high-entropy materials.

This study examines the magnetic properties of BaCo(AsO) and its unique behaviors.

Exploring how quasiparticles affect the performance of superconducting qubits in quantum computing.

Study reveals links between classical magnets and exotic spin liquid states.

This study examines how disorder affects the behavior of type II superconductors in magnetic fields.

Study reveals methods to control magnetic domain walls in nanowires.

Research on trapped ions reveals insights into their dynamics and interactions.

This article explores the nematic phases seen in fractional quantum Hall states under magnetic fields.

Examining how annealing influences the superconducting properties of niobium crystals.