Latest Articles for Materials Science

Using patent data to enhance molecular design with generative models.

NNQMD techniques are transforming material science research through enhanced atomic simulations.

Research on iron's behavior reveals effects of pressure and temperature.

Exploring how bubble collapses in fluids release and concentrate energy.

A new method enhances understanding and applications of molecular magnets.

This study examines how gases influence hypervelocity impacts and plasma formation.

Research on halide perovskites reveals new opportunities in quantum materials and electronic properties.

Research on YbPtBi reveals unique electron behavior under pressure and temperature.

Chiral spheres influence light behavior, with potential applications in pharmaceuticals and technology.

A look at the thermal properties of amorphous alumina in electronic applications.

Researchers enhance cellulose fiber production through real-time monitoring techniques.

Research on BaTiO and BiFeO multilayers reveals key factors for improved magnetoelectric performance.

Discover the future of THz detectors using graphene and black phosphorus.

Research reveals differences between charge and spin currents driven by light.

Discover the unique properties and potentials of topological insulators in technology.

Research reveals potential applications for controlling nonreciprocal transport in superconductors.

Research reveals fascinating electronic behaviors in twisted trilayer graphene structures.

Research reveals different types of shot noise in materials exposed to light.

Investigating the link between Wilson-loop topology and surface-state behavior in materials.

Research reveals potential of (Zn,Cr)Te for spintronic applications at near room temperature.

Scientists investigate how Mott insulator principles apply to light and photons.

A new model enhances understanding of solute trapping in rapidly cooled metals.

Research on self-assembly techniques leads to new photonic structures.

Research on nickelates could lead to advancements in superconducting materials.

A look into how electrons behave like a fluid in materials.

This method uses kernel techniques to efficiently find ground states in quantum systems.

Study reveals insights into quantum spin liquids and magnetic states.

Cu Bi Se showcases unique superconducting properties with potential applications in technology.

New methods are improving how we study materials under stress.

New methods improve gas pressure measurement accuracy through particle collision counting.

Research focuses on how granular materials can be designed to manage pressure effectively.

Discover how photonic crystals control light and enable advanced technologies.

Thin-film lithium niobate offers new possibilities for efficient UV light sources.

Analyzing how quantum particles interact and evolve over time.

Studying how materials fail can improve safety and disaster prediction.

Researchers use machine learning to analyze 2D images for material property predictions.

Silicon-vacancy centers in diamonds enhance quantum computing capabilities.

NaYbP O and KYbP O offer efficient cooling solutions without helium.

Discover how quantum computing reshapes electronic structure calculations in chemistry.

This article examines how fluids impact particle chains forming under shear flow.