Latest Articles for Materials Science

New methods improve molecular simulations and interactions for better accuracy.

A new method predicts probe positions for clearer imaging in ptychography.

Research reveals distinct properties of miassite under magnetic fields.

New methods improve understanding of molecular interactions and behaviors.

New hydrogenated materials show superconductivity above 80 K, promising future applications.

Innovative method integrates electron density for improved molecular property predictions.

A new algorithm finds low-energy states in quantum systems despite noise.

An overview of niobium-based superconductors and their applications in modern technology.

Exploring short-range order and local distortions in high entropy oxides.

Exploring how unique shapes influence battery efficiency and durability.

A new FFT-based method improves the study of materials with complex microstructures.

A fresh approach reveals how tiny particles interact under various conditions.

Overview of new developments in crystal technology for double-beta decay studies.

This article explores how vacancies affect graphene's unique properties and potential applications.

Exploring the thermoluminescent properties of Gadolinium aluminate for radiation measurement.

Researchers achieve long-distance polariton propagation at room temperature using perovskite metasurfaces.

This article explores how heavy and light particles interact with changing energy surfaces.

Exploring the potential of lead-free antiferroelectric materials for energy storage solutions.

Research reveals the unique properties of spinel oxides like CrO.

New multi-focus ptychography techniques improve imaging of thick materials at atomic scale.

A new approach uses machine learning to predict tensor properties of crystalline materials accurately.

We analyze numerical methods for the Cahn-Hilliard equation on changing surfaces.

Efficiently converting microwave signals to optical signals is crucial for quantum systems.

Exploring the interactions influencing electron pair formations in layered materials.

This paper discusses hyperuniformity and random measures across different spaces.

A model to reduce beam damage in scanning transmission electron microscopy.

New methods improve predictions of Curie temperature for magnetic materials.

A look into the world of superconductors and their unique properties.

Scientists uncover gapless topological phases in quantum spin chains with long-range interactions.

A study on the behavior of magnetic spin fields at high temperatures.

Researchers leverage machine learning to predict important Hubbard parameters for materials.

An overview of minimal surfaces, their energy, and recent developments in the field.

Research reveals superconductivity in twisted bilayer WSe2 under specific conditions.

An overview of DMFT and its role in studying strongly interacting electron systems.

This study examines quasicrystals and their behavior under various conditions.

Metasurfaces combine imaging techniques for clearer biological analysis.

Exploring the behavior of liquid crystals during phase transitions.

New strategies enhance cooling efficiency in optomechanical systems.

Examining particle creation in dielectric media resembling black hole behavior.

An overview of Floquet theory’s role in analyzing periodic systems.