Latest Articles for Materials Science

New methods in materials science enhance alloy discovery using machine learning.

Researchers investigate quantum behaviors of Heisenberg antiferromagnets using honeycomb lattice structures.

Investigating singlet and triplet pairings among fermions in optical lattices.

Research enhances quantum sensing by improving signal detection in noisy environments.

Exploring the movement and behavior of active filaments in nature and technology.

Exploring cobalt's impact on niobium trisulfide's magnetic behavior.

Analyzing peeling behavior to improve adhesive applications using machine learning.

A fresh approach to understanding topological materials using current noise measurements.

Exploring the fascinating properties of EuCd P and its colossal magnetoresistance.

Magnons show promise for efficient information transfer and heat management.

Research reveals how motor behavior influences active nematic materials.

Combining structural and dynamic data reveals insights into molecular behavior.

Investigating how energy and clustering affect nuclear phase transitions during heavy-ion collisions.

Learn how spintronics and carbon atoms could change technology.

LaNiO2 shows promise as a high-temperature superconductor with unique properties.

Our study reveals unexpected persistence of electronic properties in SnTe at higher temperatures.

New imaging methods reveal insights into electric fields in semiconductors and dielectrics.

Research reveals unique thermoelectric features in thin films of Cd3As2.

Exploring the significance of flat bands in electron systems.

A look at the lattice-symmetries package for quantum many-body physics.

New insights into layered materials promise advancements in energy storage and memory technology.

Research on nonreciprocal transport in superconductors aims to boost future electronics.

Examining the GKSL equations and their influence on quantum systems.

Exploring the link between chirality and electron spins in modern science.

Research reveals insights into quantum phase transitions using the spin-boson model.

This article explores how plasmas interact with semiconductor materials, focusing on electron behavior.

New insights into the behavior of SrTi₁-xVxO₃ through doping and electron interactions.

Using neural networks to enhance contact mechanics analysis and prediction.

Hamiltonian learning advances quantum systems understanding, focusing on steady states and degeneracy.

Research highlights phosphorus donors in silicon to enhance quantum operations.

PolyGET merges speed and accuracy in polymer simulations, enhancing scientific research.

Researchers study how electron beams interact with spherical nanoparticles for optical applications.

Research reveals new methods to measure heat transfer in tungsten at high temperatures.

Research reveals new spin-to-charge conversion methods in graphene and MoTe at low temperatures.

Explore the unique interactions of chiral structures with light and magnetism.

A look into path integrals and their impact on understanding complex systems.

Research reveals exciting properties of bulk alternating twisted graphite.

New methods improve heat equation solutions for irregular boundaries and interfaces.

Introducing a new method for accurate simulations of nematic liquid crystals.

Researchers explore ferrovalley materials for future electronic advancements.