Latest Articles for Materials Science

Liquid crystals bridge liquids and solids, powering screens and sensors.

Research on PbTe nanowires reveals potential for secure quantum computing applications.

Exploring the stability and significance of heliknotons in cubic chiral magnets.

New methods improve understanding of materials with localized electrons and relativistic effects.

Study reveals how soft disks transition between phases influenced by interaction types and conditions.

Explore how packing and temperature influence material behavior.

This article examines how squeezing affects topology in quantum systems.

A look at how phonon magnetic moments in materials like bilayer graphene can be controlled.

Discover new methods in topology optimization for improved structural design.

Examining how grain structures impact material performance across industries.

A look into the unique state of classical spin liquids in condensed matter physics.

BaYbSiO exhibits unique magnetic behaviors influenced by its honeycomb structure.

New techniques enhance accuracy in molecular property calculations using density functional theory.

Examining how alkali modifiers influence alkali silicate glass surfaces and their applications.

Scientists investigate magnon squeezed states using hybrid systems to advance quantum technologies.

Research reveals new ways to measure spin density using Josephson junctions.

This study explores how excitons behave in polaritonic wires under different conditions.

Explore how high-energy x-ray diffraction reveals material structures at the atomic level.

Learn about a new method for creating strong microstructures.

Research reveals complex magnetic behaviors in two-leg spin ladder systems.

A new method enhances 3D chemical imaging while reducing energy use.

Discover the latest findings in high harmonic generation within solid materials.

A new method enhances the measurement of solid-liquid friction at the nanoscale.

This article examines behaviors in physical systems with long-range interactions and conserved multipoles.

Researchers are managing antiferromagnetic states for faster memory storage.

This article investigates how Coulomb drag and heat transfer operate in strange metals.

Geometric Latent Diffusion Models enhance 3D molecule creation for scientific applications.

Research on FeBr2 explores its unique electronic and magnetic properties.

This article presents a method to study interactions between weak acids and polymers.

Research delves into kagome lattices and their unique superconducting properties.

Researchers reveal innovative methods for controlling light in complex materials.

This article explores how liquid particles move and their unique dynamics.

Researchers combine machine learning and scaling theory to improve wave confinement studies.

A look at tracking schemes for resonance frequency measurements in tiny devices.

Research reveals tantalum as a key material for improving qubit efficiency.

A simplified approach enhances the study of topological orders and anyons in quantum physics.

Research reveals how Q-factor influences polariton behavior and energy transfer in materials.

Exploring how layer thickness and disorder affect conductivity in superlattices.

Fracton phases reveal unique behaviors in particles, challenging traditional material science.

Examining how magnons scatter in skyrmion crystals reveals key physical principles.