Latest Articles for Materials Science

An overview of light-matter interactions and the limitations of the Jaynes-Cummings model.

This article compares Kubo and QFT models for graphene's electrical conductivity.

Examining the impact of Coulomb potential on electron paths during ionization.

Research focuses on efficient energy management during rapid phase changes.

Examining how tramp elements affect steel's durability and performance.

Examining how static and evolving disorder affect wave movement in materials.

Research reveals how interactions affect localization in Bose-Einstein condensates.

Exploring how dimensionality impacts Anderson localization in quantum systems.

A look into understanding sudden changes in mathematical functions.

Examining the necessity of hydrogen in superconducting nickelates and its implications.

New hybrid models improve predictions of material behavior under cyclic stress.

Research reveals how stacking affects the electronic properties of NbSe layers.

Silicon carbide offers new opportunities for quantum communication, enhancing security and distance.

Examining how computational methods improve understanding of nickel-based superalloys.

OLRG offers a fresh approach to better simulate complex quantum systems.

This study examines how temperature influences copper electrode performance under high electric fields.

Twisted bilayer graphene reveals unique electronic properties under pressure and twist angles.

Research on twisted bilayer graphene reveals unique electronic properties and potential applications.

Microgels' properties pave the way for innovations in various industries.

Nodal line semimetals show promise in improving thermoelectric energy conversion.

A method to prepare two-species ion crystals using a linear Paul trap.

Researchers develop new methods for preparing Bethe states in quantum systems.

An analysis of universal MLIPs in predicting surface energies of materials.

Exploring recent advancements in DFT to enhance metal simulations under varying conditions.

SmCoIn5 showcases intriguing electronic and magnetic properties due to electron interactions.

New methods improve accuracy and speed in predicting material fatigue.

Study reveals how light affects the electronic states of 1T-VSe material.

Examining nonlinear behaviors in three-dimensional materials under magnetic influence.

Research on LaCrO and LaMnO layers could improve electronic devices.

This article explores the impact of iron doping on the properties of Weyl semimetals.

A novel approach improves the estimation of force constants in crystal materials.

Researchers observe unique behavior in two-component superfluid systems.

This research sheds light on how charged particles fluctuate under different conditions.

This study examines how hydrogen affects steel's grain boundaries and mechanical strength.

Research reveals how imperfections affect the behavior of dipolar Bose gases.

Examining how fermions behave under magnetic influences and transitions between phases.

Research improves domain engineering in lithium niobate and tantalate crystals for optical applications.

Research explores how excitons in nanocrystals affect light emission and brightness.

Exploring unique electronic properties at the BiSe and EuS interface.

Study reveals a THz-assisted method for investigating silica matrices without damaging biomolecules.