Physics - Materials Science

This article explores the impact of solidification conditions on grain growth in Magnesium-based alloys.

Study reveals how light affects the electronic state of ZrTe.

Discover the intriguing structure and magnetic behavior of NaFePO(SO).

New GdOsSi material exhibits charge density wave at room temperature.

Exploring the unique properties of ZnO for various technological applications.

Research explores methods to enhance predictions of electron-phonon interactions in materials.

Discover the uses and benefits of hydrogels across various fields.

New models enhance hydrogel simulations for bioprinting applications.

Phosphorene nanoribbons show promise in electronic applications due to unique properties.

Using machine learning to model and predict spins in magnetic materials.

This article examines how defects affect the performance of ferroelectric materials.

Hybrid DFT methods enhance accuracy and efficiency for studying complex systems in chemistry.

Research on altermagnets reveals how light influences their magnetic properties.

Research reveals surprising spin behaviors in CoNbO near quantum critical points.

Exploring how stress and viscosity affect waves in fluids and solids.

This article examines internal stresses in iron-chromium alloys due to rapid solidification.

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.

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

A look into the fascinating characteristics of alkali superoxides and their behavior.

TaRhTe's unique layers alter its electronic behavior, promising advances in technology.

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

Crystalformer efficiently predicts material properties using advanced attention mechanisms.

Research focuses on improving electricity generation from light using lasers and advanced materials.

New techniques enhance our understanding of dislocation behavior in materials.

Exploring the role of NV centers in measuring material properties at the nanoscale.

Research reveals how structure impacts the properties of polymeric carbon nitrides.

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

Research highlights the potential of Janus MXenes in thermoelectric applications.

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.

Research enhances imaging techniques using nanodiamonds for clearer NMR signals.

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

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 how transition metal doping alters TiS's magnetic and electronic properties.

Researchers examine lithium niobate tantalate's unique properties and potential applications.

Exploring how carbonated silicate grains influence cosmic dust and star formation.

Machine learning techniques enhance the discovery of new materials for various industries.

New findings on THz magnons could enhance technology performance and speed.