High magnetic fields directly enhance the amplitude and correlation length of stripe order in a cuprate superconductor far above the vortex melting transition, indicating a coupling mechanism independent of superconductivity suppression.
Castro Neto, F
6 Pith papers cite this work. Polarity classification is still indexing.
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Pith papers citing it
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Exact vs. restricted particle-hole dynamics in graphene flakes after optical quench shows periodic structures captured by low-order excitations but confined ones require higher-order contributions, positioning the setup as a quantum-computing benchmark.
DFT study reports that As substitution and interstitial doping in MoS2 monolayer introduce midgap defect states and shift the Fermi level to produce p-type or n-type character depending on site.
Quantum confinement in 2D hexagonal crystals like graphene and TMDs produces discrete electronic and excitonic spectra with strongly amplified interactions that enable correlated quantum states.
Certain biomembrane shapes like cylinders, spheres, tori, biconcave discoids, and Delaunay surfaces form a geometric group independent of the specific biomembrane equation when pressure, tension, and bending moduli meet particular conditions.
Exciton polaritons in microcavities form synthetic photonic crystals with engineered band structures and interactions for exploring many-body physics from mean-field to quantum regimes.
citing papers explorer
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Direct High-Magnetic-Field Coupling to Stripe Order in a Cuprate Superconductor
High magnetic fields directly enhance the amplitude and correlation length of stripe order in a cuprate superconductor far above the vortex melting transition, indicating a coupling mechanism independent of superconductivity suppression.
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Interaction-driven dynamics in graphene flakes as a benchmark for quantum simulation
Exact vs. restricted particle-hole dynamics in graphene flakes after optical quench shows periodic structures captured by low-order excitations but confined ones require higher-order contributions, positioning the setup as a quantum-computing benchmark.
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First-principles study of the impact of As doping on the structural and electronic properties of MoS$_2$ monolayer
DFT study reports that As substitution and interstitial doping in MoS2 monolayer introduce midgap defect states and shift the Fermi level to produce p-type or n-type character depending on site.
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Correlated Quantum Phenomena in Confined Two-Dimensional Hexagonal Crystals
Quantum confinement in 2D hexagonal crystals like graphene and TMDs produces discrete electronic and excitonic spectra with strongly amplified interactions that enable correlated quantum states.
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Liquid Crystal Theory of Biomembranes
Certain biomembrane shapes like cylinders, spheres, tori, biconcave discoids, and Delaunay surfaces form a geometric group independent of the specific biomembrane equation when pressure, tension, and bending moduli meet particular conditions.
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Synthetic Polariton Matter in the solid state
Exciton polaritons in microcavities form synthetic photonic crystals with engineered band structures and interactions for exploring many-body physics from mean-field to quantum regimes.