Uniaxial strain and atomic reconstruction in MoSe2-WSe2 heterobilayers deterministically form quasi-1D domain walls that confine interlayer excitons, with confinement strength tuned by twist angle and electric field.
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Twisted trilayer hBN exhibits electric-field-tunable super moiré domains that host reconfigurable arrays of quantum dots supporting localized quantum harmonic oscillator states.
Pressure tunes band flatness and geometry in tMoTe2 to control FCI and GWC phases and their topological transitions at fractional fillings.
citing papers explorer
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Control of atomic reconstruction and quasi-1D excitons in strain-engineered moir\'e heterostructures
Uniaxial strain and atomic reconstruction in MoSe2-WSe2 heterobilayers deterministically form quasi-1D domain walls that confine interlayer excitons, with confinement strength tuned by twist angle and electric field.
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Super Moir\'e Domain Tessellations, Sliding Ferroelectricity, and Reconfigurable Quantum Dot Arrays in Twisted Trilayer Hexagonal Boron Nitride
Twisted trilayer hBN exhibits electric-field-tunable super moiré domains that host reconfigurable arrays of quantum dots supporting localized quantum harmonic oscillator states.
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Pressure-Tunable Generalized Wigner Crystal and Fractional Chern Insulator in twisted MoTe$_2$
Pressure tunes band flatness and geometry in tMoTe2 to control FCI and GWC phases and their topological transitions at fractional fillings.