Latest Articles for Materials Science

New model improves accuracy and speed in atomic-level research.

This article explains how scientists study key ions in water using computational methods.

FeGeTe reveals unique behaviors under temperature and magnetic influences, impacting technology.

A new method solves complex quantum problems more efficiently using quantum computers.

Studying edge singularities and their implications in fermionic interactions.

Researchers are studying toroidal dipoles for advancements in technology and materials.

Hexagonal materials show promise in combining magnetic and electric properties for modern electronics.

Research reveals the resilience of Nd-based pyrochlore magnets in varying conditions.

Examining low-energy dynamics of molecules near conical intersections.

Study reveals how simulations help visualize radiation damage in tungsten metal.

This study examines how light spreads in materials with scattered beads.

New strategies enhance accuracy in predicting drug compound effectiveness.

A look into the unique electronic behaviors of biphenylene network materials.

A new method for associative memory using spintronics enhances efficiency in computing.

Exploring the fascinating properties and potential applications of topological insulators.

Researchers demonstrate methods to create mass in quasiparticles using optical gain and loss.

Research reveals altermagnetic properties of RuF, advancing spintronic applications.

This article discusses the development and testing of sodium-ion batteries using hard carbon anodes.

Twisted bilayer graphene reveals unique electronic states and behaviors under magnetic fields.

Researchers highlight the energy conversion potential of crystalline o-CsCuS.

Exploring how particles behave over time in constrained environments.

Discover how optical cavities change molecular behaviors and chemical reactions.

AnisoGNN uses AI to predict polycrystalline material properties with less data.

Research focuses on improving the growth of InAs nanowires using a new model.

Researchers reveal new findings about water's liquid phases under varying conditions.

This new method simplifies laser integration across various materials, enhancing performance in photonics.

This study examines how particles combine and evolve in a defined spatial area.

Research improves spin coherence times in diamond, enhancing quantum technology applications.

Research on silicon anodes and ionic liquids aims to improve battery performance.

A new model speeds up the search for superconductors using machine learning.

Investigating how current-induced forces change energy flow in small systems.

This article explores Bloch oscillations, quantum geometry, and electron response to electric fields.

Recent studies reveal surprising transitions in cuprate materials from superconductors to metals.

This study examines how impurities move and interact in complex environments.

Research improves measurement techniques in strong field ionization for attosecond science.

Research reveals low-energy transitions in CeAgGe linked to crystal electric fields.

Examining how light affects electrical properties of vanadium oxides and their applications.

Research on FAPbI3 nanocubes reveals new insights into excitons and material properties.

An overview of superconducting spin valves and their implications for electronics.

This article examines how viscoelastic tapes detach from surfaces and its applications.