Latest Articles for Materials Science

Explore the evolving world of dynamic polymers and their applications.

A look at quantum phase transitions and methods to minimize excitations.

Recent developments improve efficiency and applications of SHG in various technologies.

A new method links excitons with mechanical systems, boosting quantum technology potential.

Researchers study complex behaviors of frustrated quantum magnets at low temperatures.

Examining the potential of the Kekulé Valence Bond Solid state in graphene.

Research on MgB₂C and NaBC reveals potential for ambient-pressure superconductors.

IrTe2's phase transitions reveal insights into its electronic behavior and potential applications.

New detection method improves measurement of BBO crystal interactions.

Scientists study Majorana bound states using quantum dots for improved quantum computing.

Exploring the unique features of NbOCl monolayer in materials science.

An overview of unique behaviors in non-Hermitian quantum systems.

Chiral tellurium showcases fascinating electrical behavior influenced by its structure and magnetic fields.

A look at the 20-vertex model and its significance in statistical physics.

New method improves efficiency in electron simulations using Fourier neural operators.

New methods simplify the simulation of open quantum systems in quantum physics.

Examining the interplay between Kondo physics and magnetic anisotropy in rare earth materials.

Learn about the fascinating behavior of quantum wells in electronics and energy devices.

Investigating unique behaviors in superconductors through fractional Shapiro steps.

New methods enhance measurement accuracy of van der Waals superconductors.

Researchers improve superconductivity in iron selenide through innovative interfaces.

Study reveals unique magnetic properties of FeP SiO under varying conditions.

Examining magnetic behaviors in square lattices and their significance in technology.

A look at the behavior of electromagnetic waves in unique materials.

Explore how microstructure influences the performance of hyperelastic materials.

Study reveals how material layers affect fracture behavior in fluid-filled environments.

Researchers demonstrate increased wave speeds using non-Hermitian lattices.

Research reveals ultrasonic processing can enhance metal quality in additive manufacturing.

Exploring non-local heating and cooling effects in thermoelectric materials at the nanoscale.

Exploring the Floquet SSH model's insights into energy flow through materials.

A new framework predicts crack patterns in concrete for improved structural integrity.

New methods improve efficiency in studying periodic systems for better material insights.

Researchers develop a new approach utilizing quantum devices to compute excited states efficiently.

Exploring the fascinating behaviors of composite fermions and the CFL state.

This article discusses quantum control of oscillators using Kerr-cat qubits and their implications.

Research focuses on improving light output in nanocomposite scintillators for particle detection.

New neutron scattering techniques enhance skyrmion studies, improving spintronic device design.

Researchers improve models for open quantum systems using the polaron master equation.

New models help design materials that control wave behavior effectively.

Research reveals unique properties of quantum skyrmion liquids, advancing our grasp of magnetism.