Latest Articles for Condensed Matter Physics

Researchers investigate the unique bands in YRuSi for potential technological advancements.

Research highlights the role of strain and magnetic fields in honeycomb lattices.

A look at how electron interactions shape material properties using the Extended Hubbard Model.

This research examines how thermal vibrations affect light behavior in quantum fluids.

A look into the unique properties and challenges of quantum spin liquids.

This study examines the pseudogap behavior and its relation to thermal fluctuations.

Research reveals new insights into one-dimensional topological superconductivity using van der Waals heterostructures.

Study reveals how interactions affect transitions between Luttinger liquids and Anderson glasses.

Study reveals insights into the unique magnetism of pyrochlore ruthenates.

This article examines how NG bosons respond to long-range correlations and temperature changes.

Research on twisted WSe₂ reveals unique insulating properties and electronic behaviors.

This study investigates exciton behavior in a hybrid Bose-Fermi Hubbard system.

Researchers uncover complex superconducting phases in CeRh As with unique atomic structures.

Learn about moiré heterostructures and their fascinating electronic properties.

Research on graphene reveals key insights into superconductivity and Cooper pair dynamics.

A look into the complex behaviors of spin glasses and their quantum properties.

A look into bosonic ladders and their unique phases in condensed matter physics.

Research reveals potential for superconductivity in twisted trilayer graphene's unique electronic phases.

A new mapping connects clock-spin models to fermionic systems for deeper insights.

Study reveals unique behaviors of confined states in two-dimensional quasicrystals.

Study reveals key insights on the pseudogap phenomenon in Tl-1223 superconductors.

A look into the unique state of classical spin liquids in condensed matter physics.

BaYbSiO exhibits unique magnetic behaviors influenced by its honeycomb structure.

Research reveals new insights into the anomalous Hall effect in noncollinear antiferromagnets.

A look into the modified harmonic oscillator potential and its properties.

Research on radial spin textures highlights their role in material properties and applications.

Research reveals the complex relationship between atomic arrangements and charge density waves in cuprates.

Recent findings on twisted bilayer TMDs reveal fascinating electronic behaviors and potential applications.

This article explores driven-dissipative condensates and their unique phase and frequency behavior.

Research delves into kagome lattices and their unique superconducting properties.

Exploring how layer thickness and disorder affect conductivity in superlattices.

Examining how magnons scatter in skyrmion crystals reveals key physical principles.

Researchers study spin liquids and their behavior after quantum quenches for potential applications.

A look into the complexities of electric polarization in Chern insulators.

Investigating unique electronic behaviors in topological semimetals through atomic arrangements.

Investigating magnon condensation in quantum magnets with spin-orbit coupling and external fields.

This study examines how quarks and mesons behave under extreme conditions.

This article explores the dynamics of quantum impurities using the Anderson impurity model.

Research reveals key electronic properties of Sr RuO using advanced Raman techniques.

A look into the Kitaev honeycomb model and its implications for quantum liquids.