Latest Articles for Materials Science

Research in photonics leads to enhanced quantum technologies and simulations.

Researchers achieve better control over exciton behavior in quantum dots.

Exploring unique properties and behaviors of topological orders in materials.

A model enhances the understanding of electrolyte movement in porous materials.

A fresh model improves understanding of how fibers stick and pull apart.

A new method combines quantum and classical techniques for better Hamiltonian modeling.

Research reveals insights into surface states affected by spin-orbit coupling.

A look at similarity constrained coupled cluster theory's role in molecular understanding.

Exploring the superconducting properties of twisted graphene structures and their applications.

Carbon in hBN creates stable defects for single photon emission, aiding quantum tech.

Exploring advancements in superconductors and their potential for future technologies.

This article examines how fabrication techniques impact superconducting device performance.

Exploring the impact of sound waves on fluid movement for diverse applications.

Researchers enhance conversion efficiency using innovative magnon-based interfaces.

A look into the behavior of viscoelastic materials when deformed.

Exploring the behavior and applications of self-lubricating multicomponent drops.

Researchers investigate quaternary hydrides for potential room-temperature superconductivity.

This article examines how particle shapes influence their assembly behavior.

New sensors provide precise pressure measurement in microfluidic systems.

Research on Floquet materials reveals new possibilities in high-order sideband generation.

Exploring the significance and representation of residual stresses in engineering materials.

A new approach improves simulations for quasi-2D particle interactions.

Machine learning aids in predicting crystal structures more efficiently than traditional methods.

New methods improve efficiency and accuracy in quantum system simulations.

This study examines how different forces affect sliding and rupture dynamics.

Insights into tungsten atom movement in layered materials and its implications.

An overview of superconductivity mechanisms and electron interactions in various materials.

This study reveals how active liquids influence colloidal particle dynamics and cluster formation.

An overview of light-matter interactions and the limitations of the Jaynes-Cummings model.

This article compares Kubo and QFT models for graphene's electrical conductivity.

Examining the impact of Coulomb potential on electron paths during ionization.

Research focuses on efficient energy management during rapid phase changes.

Examining how tramp elements affect steel's durability and performance.

Examining how static and evolving disorder affect wave movement in materials.

Research reveals how interactions affect localization in Bose-Einstein condensates.

Exploring how dimensionality impacts Anderson localization in quantum systems.

A look into understanding sudden changes in mathematical functions.

Examining the necessity of hydrogen in superconducting nickelates and its implications.

New hybrid models improve predictions of material behavior under cyclic stress.

Research reveals how stacking affects the electronic properties of NbSe layers.