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The authors demonstrate the tunability of moiré potential and emergent moiré exciton Rydberg states in a monolayer transition metal dichalcogenide governed by an adjacent twisted bilayer graphene near the magic angle with gate-tunable local charge density.
The authors imprint a moiré potential on a remote monolayer semiconductor through the moiré potential created in a remote MoSe2/WS2 moiré bilayer. The imprinted moiré potential enables gate-controlled generation of flat bands and correlated insulating states in the targeted monolayer.
Autonomous assembly, reconfiguration and disassembly are observed in living aggregates, but are difficult to replicate in synthetic soft matter. Here mechanically interlocked responsive ribbons form transient viscoelastic solids for the on-demand assembly of functional materials.
Rhenium chalcohalide cluster compounds are promising photoluminescent materials. Here the authors report a new material in this family, Rb6Re6S8I8, which shows broad photoluminescence (PL) range, high PL quantum yield and long PL lifetime.
Employing nonlinear, time-resolved terahertz spectroscopy to study condensate dynamics on Ta2NiSe5—a narrow-bandgap semiconductor and putative excitonic insulator—the authors reveal enhanced terahertz reflectivity upon photoexcitation and condensation-like temperature dependence below the structural transition critical temperature.
The authors combine laser excitation and scanning tunnelling spectroscopy to visualize the electron and hole distributions in photoexcited moiré excitons in twisted bilayer WS2. This photocurrent tunnelling microscopy approach enables the study of photoexcited non-equilibrium moiré phenomena at atomic scales.
The self-assembly of metallic nanoparticles on oxide supports via metal exsolution relies on dopant transport, but strong electrostatic gradients and space charges typically control the properties of surfaces. The surface–dopant interaction is shown to be the main determining factor for the exsolution kinetics of nickel in a perovskite system.