Latest Articles for Materials Science

Utilizing simple models for effective exploration of chemical compounds.

Exploring Majorana nanowires and their potential role in quantum computing.

This study presents a new way to control droplet movement using light.

Study reveals the unique properties and ordered states of twisted bilayer graphene.

A look at how nickel, palladium, rhodium, and iridium react to high pressure.

Researchers investigate the impact of disorder on Majorana nanowires for future computing.

Researchers analyze how wave propagation changes in non-reciprocal materials.

Researchers investigate nitrogen-doped lutetium hydride for its superconducting potential.

New on-site pipe production technique aims to enhance UHV systems for the Einstein Telescope.

Altermagnets could change how we use electronics by combining charge and spin.

Research reveals the role of coherent transition radiation in studying fast electrons.

New models enhance understanding of heat transfer in materials during rapid heating.

Research reveals unique properties of antimony thin films for future electronic applications.

This study investigates the impact of material defects on SRF cavity performance.

New methods improve stability of indenene for electronics using graphene.

Exploring the creation and manipulation of spacetime magnetic hopfions.

Research uncovers unique magnetic states in layered materials through IL-DMI.

A look at the Hilbertian projection method in constrained topology optimization.

New techniques using X-ray free electron lasers improve our understanding of magnetic materials.

This study reveals how the shape of particles affects their arrangement into crystals.

A new approach enhances DFT accuracy for strong electron correlation in iron complexes.

Research unveils methods to study transition metal complexes under light exposure.

Research reveals complex magnetic behaviors in EuPtSi using resonant elastic X-ray scattering.

Exploring the significance of phase transitions in Yang-Mills theories and their implications.

Research uncovers how light affects chemical reactions in unique environments.

New techniques enhance simulations of quantum states in materials using machine learning.

Investigating unique magnetic properties of uranium compounds under varying conditions.

Research reveals how temperature influences magnetic properties in BaTiO and CoFeB structures.

Study reveals effects of electron irradiation on magnetite's Verwey transition characteristics.

Innovative methods reveal insights into transition metal electronic structures.

New method enhances mapping of molecular transformations.

Introducing MatSci-NLP to improve text processing in materials science.

A new method improves simulations in molecular energy transfer.

A new method merges machine learning with finite element analysis for thermoelasticity.

Exploring how symmetry and energy conservation shape light interactions with cylindrical objects.

Research highlights the potential of 2D materials for efficient entangled photon production.

Researchers develop methods for predictable magnetization, enhancing future computing technologies.

Examining how charge affects nanoparticles in various solutions.

Research highlights the potential of magnons in advanced antiferromagnetic materials.

A look into the unique phase transitions of Weyl materials and their electronic properties.