Latest Articles for Materials Science

New research highlights how rhombus defects enhance the stability of quasicrystals.

Research shows thicker kagome films can also exhibit superconductivity.

Research shows carbide interlayers can enhance heat transfer in electronics.

A new method combines manifold learning with model order reduction for efficiency.

An examination of crumpled sheets and their surprising behaviors in materials science.

New algorithms enhance understanding of surface states in photonic and acoustic systems.

This article explores methods to predict how stressed materials respond to forces.

Research on BaFe(As,P) enhances understanding of superconducting behavior and properties.

Research on multiterminal Josephson junctions reveals unique properties of superconductors and normal metals.

Exploring the unique properties and applications of black phosphorus in electronics.

A look into the innovative altermagnetic material 2D-CRO and its potential uses.

A novel approach to create clean surfaces for cubic perovskite oxides.

New methods for designing hyperuniform materials based on biological cell arrangements.

New method enhances accuracy in placing tiny gold droplets for material studies.

Exploring the behavior and optimization of liquid crystal drops.

Molecular spin systems are crucial for advancements in quantum technologies.

Exploring new waveguide designs to reduce energy loss in phononic systems.

This study examines how liquid nano-threads respond to disturbances and thermal movements.

Exploring how voltage affects soap film bridges and their behavior.

Exploring how particle size affects photoluminescence in materials for energy applications.

Research reveals unique properties of twisted bilayer graphene and its potential applications.

Research highlights energy dynamics of electrons in plasma for improved beam quality.

Examining sputtering issues in heavy-ion experiments for superheavy nuclei synthesis.

This article examines the unique features of driven systems and their topological characteristics.

Examining how particle shapes influence 3D printing quality and efficiency.

Analyzing temperature jumps and energy transfer in gases with multiple atoms.

Investigating the iron-magnetite interface reveals insights for material improvements.

Research on light and molecular interactions leads to improved simulation techniques.

Exploring the potential of membrane antennas for observations from the Moon.

New method streamlines analysis of particle movement in quantum systems.

New techniques improve understanding of material behavior under stress and heat.

New methods improve molecule creation for drugs and materials.

Research focuses on YbOCl's magnetic behavior and interactions at low temperatures.

Study examines how inverted flags interact with flowing fluids and their energy capture potential.

A look at the Hall effect and its significance in organic semiconductors.

Exploring how strain effects in SWCNTs can transform electronic devices.

hBN spin defects enhance precision in quantum sensing across multiple fields.

Research reveals how design impacts light movement in valley photonic crystals.

Study of CeRhIn's magnetic behavior at low temperatures and under magnetic fields.

Research highlights the unique behavior of layered PtSe in electronics.