Latest Articles for Materials Science

Recent progress in simulating quantum states enhances applications in materials and chemistry.

A study on using the Birnbaum-Saunders distribution for better fatigue life estimates.

Nickelates show unique properties under hole doping, impacting superconductivity potential.

This article examines the swift reversal of magnetization in ferromagnetic spin-valves.

Exploring how active particles move within complex polymer structures and their implications.

This study highlights the manipulation of electron spin in graphene junctions using magnetic fields.

Exploring the link between topology and electron behavior in materials.

This article examines how waves behave in materials that can deform plastically and elastically.

Exploring two unique systems that utilize piezoelectric materials for advanced stability.

Insights into topological phases and their implications for technology.

This study reveals how imperfections in materials affect their thermalization process.

A new method simplifies light interaction analysis in layered materials.

Research reveals insights into vanadium dioxide's transition from insulator to metal.

Research improves control over quantum wells with independent electric contacts.

A look into how dislocations move and interact in metals.

Researchers enhance NMR and MRI sensitivity through innovative hyperpolarization methods.

Researchers study unique jets formed in Bose-Einstein condensates, revealing complex atomic interactions.

Me-graphene shows promise for future electronic applications with unique mechanical properties.

Researchers reveal how defects in alloys can influence material performance and design.

New method enhances understanding of platinum-rhodium nanoparticles for improved catalytic efficiency.

Research reveals fascinating properties of Dirac exceptional points in non-Hermitian systems.

Researchers reveal how energy loss creates stable topological edge states in materials.

Investigating the unique properties and applications of twisted bilayer graphene.

CrysFieldExplorer simplifies the optimization of crystal electric field parameters.

Research reveals how polyelectrolytes influence microgel stability and flow properties.

Active matter showcases unique behaviors from particle motion and interactions.

A new approach improves efficiency in simulating complex chemical systems.

An overview of spin-pumping effects in TIs and ferromagnetic metals.

A guide to understanding anyon condensation in quantum systems.

This study examines calcium-based electrolytes and their dynamics in battery applications.

Discover how elastic strips coil inside tubes and its implications in various fields.

A look at silicene, germanene, and stanene and their intriguing properties.

New methods improve understanding of quantum materials through computational techniques.

A novel approach to measure exciton properties in two-dimensional materials.

Researchers improve measurements of ruthenium's fluorescence yields and Coster-Kronig factors.

Research reveals new electronic properties in twisted bilayer MoS influenced by atomic movements.

This study focuses on particle behavior in confined spaces, relevant for technology and biology.

Glass innovations are key to improving solar panel performance and sustainability.

A new algorithm improves the determination of habit planes in steel.

Twisted bilayer graphene showcases unique superconducting properties through Josephson junctions without magnetic materials.