Latest Articles for Materials Science

A new method that efficiently simplifies complex data for better results.

Researchers study excitons in MoS to unlock new light technologies.

Discover the fascinating world of spin-orbit coupling and its impact on modern technology.

Discover how Floquet-Bloch valleytronics is set to transform electronics and quantum computing.

Discover how FeSe superconductors hold promise for future technologies through intrinsic pinning.

Discover how EuFe(As,P) blends superconductivity and magnetism in unexpected ways.

Discover the unique properties of MnB(OH) and its potential in technology.

Discover how light can turn materials into superconductors.

Explore how chaos affects fluid behavior in porous materials.

Discover how piezoelectric materials like LiSnX can power devices from our daily activities.

Altermagnets offer unique properties that could transform technology and magnetism.

Exploring the superconducting properties of strontium titanate and its complexities.

A deep dive into QQHE and its relationship with Coulomb disorder in semimetals.

Explore how materials behave during phase changes and their practical applications.

CeGaGe reveals unique properties that could transform electronic technologies.

Research reveals how missing atoms change graphene's stiffness and flexibility.

Discover how surface-plasmon polaritons are changing technology and materials science.

Explore the fascinating world of tiny particles and their big effects.

Exploring how phonons and spins transform magnetism for future technologies.

Combining nickel and hafnium oxide could transform technology with electric control of magnetism.

Explore how Curie temperature influences alloy behavior in technology and materials.

Discover the fascinating world of nanostructures and their impact on technology.

Scientists combine high pressure, magnetic fields, and low temperatures to study quantum materials.

CrOCl shows promise for smarter, energy-saving technologies through unique magnetic properties.

Plasmonic gap structures promise exciting advances in science and technology.

Rhenium withstands extreme heat and pressure, vital for high-performance applications.

Exploring defects and phases in gauged linear sigma models reveals unique particle interactions.

GRFsaw makes microstructure design accessible and efficient for engineers and scientists.

Discover how tiny particles absorb shocks and transform our understanding of materials.

Explore the hidden complexities of fluid dynamics and contact lines.

A fresh approach to simulate fermions using qudits enhances quantum research.

Discover how flat-band lattices control waves and vibrations uniquely.

Discover how unique materials challenge the rules of superconductivity.

Discover how molecular structure impacts charge movement in organic semiconductors.

Discover how the Diffusion Monte Carlo method helps understand particle behavior.

Discover how temperature differences create electricity in thermoelectric junctions.

Discover how advanced optimization techniques enhance material design and experimental efficiency.

Discover how quantum dots interact and create intriguing Kondo behaviors in unique arrangements.

New methods are changing how scientists study electron behavior in atoms.

A game-changing method in molecular simulations cutting costs and improving efficiency.