Latest Articles for Materials Science

Research on superconducting diode effect promises to advance electronic device efficiency.

Examining how ring structures of quantum emitters enhance energy transport and collection.

Explore how twisting affects elastic filaments' energy storage and everyday applications.

A technique improves understanding of electron structures in organic materials.

Explore the impact of spin-orbit coupling on electronic properties and applications.

A deep learning approach for analyzing wood fibers and vessels efficiently.

A look at Monte Carlo methods in material science.

New technique enhances muon experiments, enabling real-time data collection.

Researchers investigate how temperature influences structure in layered LiV materials.

Exploring the latest developments and implications of discrete time crystals in quantum physics.

New analyzer improves TR-ARPES for studying material dynamics.

V2FeAl's atom arrangement impacts its magnetic properties, crucial for technology.

Research reveals how flat band materials could lead to higher temperature superconductors.

This article examines how soft materials change shape during growth.

Exploring the role and applications of Green's function theory in modern physics.

Examining how noise affects phase transitions in polariton condensates.

Study reveals interaction between active and passive particles in rafts.

Understanding superionic ice sheds light on icy planets' conditions.

Exploring the effects of mass changes in quantum systems and their real-world applications.

Discover how exceptional points enhance sensing technologies using spherical resonators.

This study explores superconductivity in a Dirac semimetal through temperature and magnetic field effects.

Exploring the potential of silicon hole spin qubits for quantum technology.

Explore how partial charges impact molecules and chemical bonds.

Exploring YIG thin films and their potential in electronics and magnetism.

Scientists study how decoherence affects the stability of topological states in quantum systems.

NMR shifts reveal complex behaviors in cuprates and their electronic properties.

Analyzing GPT-NeoX and LLaMA models for materials science applications.

A machine learning model improves predictions of complex molecular properties based on SMILES code.

Study reveals how observing free fermions influences their quantum dynamics.

New modeling techniques enhance understanding of light scattering in materials.

Research shows how electric fields change properties of bilayer graphene.

This study examines how charge distribution affects noise in graphene devices.

Exploring how aging and composition affect metallic glasses' behavior under stress.

This article discusses the properties and applications of one-dimensional non-hermitian systems.

Examining how disordered materials return to equilibrium through stretched-exponential relaxation.

Investigating relationships between toric code, topological superconductor, and Ising model.

A new solar cell architecture enhances energy conversion with GaAs integration.

Study reveals laser effects on magnetic properties and spin waves in materials.

Exploring the impacts of disorder on the Thouless pump and Floquet states.

Research on new ways to make brittle materials tougher through composite designs.