Latest Articles for Materials Science

This article examines the complexities of sampling from the continuous random energy model.

Researchers use neural networks for better modeling of complex nonstoichiometric materials.

Examining the complex behavior of materials during superconductor-insulator transitions.

A detailed look into the structure and properties of LK-99.

Machine learning aids in controlling quantum dots for future computing.

Examining helium's behavior in magnetic fields and its measurement applications.

Researchers work to enhance light interactions using gain materials in metal cavities.

Research reveals how materials change shape under movement and stress.

Investigating the unique properties of bilayer graphene and its potential in quantum computing.

Explore the unique properties of non-Hermitian and Hermitian lattices.

This study examines how Cu-Zr metallic glasses respond to repeated stress.

This article reviews the properties and applications of aluminium syntactic foams.

Researchers enhance AFQMC simulations using automatic differentiation for better accuracy.

New methods enhance simulation efficiency for superconducting magnets and HTS materials.

Study reveals thermal conductivity properties of 10H-SiC thin films for high-temperature applications.

Researchers study how relativistic electrons behave at barriers, drawing parallels to light.

Research explores spin squeezing using Silicon-Vacancy centers and acoustic waves for better quantum measurements.

An overview of the Wigner reaction matrix and its role in wave interactions.

Research highlights the potential of hBN for quantum state generation.

Research on nitridized aluminum reveals its potential in superconducting applications.

Examining how temperature affects h-BN growth on Ir.

Exploring emergent inductance in strongly correlated magnets and its potential applications.

Research reveals methods to boost light intensity using plasmonic structures.

Recent findings reveal a new type of quantum anomalous Hall effect in materials.

Exploring Majorana fermions and their potential in quantum computing and spintronics.

Research explores bilayer CrI/WTe for efficient spintronic devices.

Researchers unveil ZIA phases, promising new properties and applications in technology.

New models enhance understanding of proton and hydroxide interactions in water.

Recent studies challenge LK-99's potential for room-temperature superconductivity.

Using polarized light to favor specific enantiomers in chemical reactions.

Researchers improve control over light interactions with innovative resonators.

Learn how bubbles form and interact in liquids during phase changes.

Research reveals strong coupling effects in spin-magnon dynamics using Kerr nonlinearity.

This study investigates how tiny particles behave in unique liquid crystal environments.

Study reveals how imperfections affect resonator behavior.

Soft snake robots are evolving to navigate obstacles more effectively.

Scientists use pair photoemission to analyze electron behavior in materials.

Exploring the unique behaviors of heavy fermion compounds with Cerium and Europium ions.

Topological insulators feature intriguing properties that could transform electronics and quantum computing.

Exploring the role of nonlinearities in wave behavior through orthogonal polynomials.