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Spontaneous supercrystal formation during a strain-engineered metal-insulator transition

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arxiv 2311.11842 v1 pith:2FD4WQ2K submitted 2023-11-20 cond-mat.mtrl-sci cond-mat.str-el

Spontaneous supercrystal formation during a strain-engineered metal-insulator transition

classification cond-mat.mtrl-sci cond-mat.str-el
keywords electronicformationmottsupercrystaltransitionanisotropicduringfilm
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Mott metal-insulator transitions possess electronic, magnetic, and structural degrees of freedom promising next generation energy-efficient electronics. We report a previously unknown, hierarchically ordered state during a Mott transition and demonstrate correlated switching of functional electronic properties. We elucidate in-situ formation of an intrinsic supercrystal in a Ca2RuO4 thin film. Machine learning-assisted X-ray nanodiffraction together with electron microscopy reveal multi-scale periodic domain formation at and below the film transition temperature (TFilm ~ 200-250 K) and a separate anisotropic spatial structure at and above TFilm. Local resistivity measurements imply an intrinsic coupling of the supercrystal orientation to the material's anisotropic conductivity. Our findings add an additional degree of complexity to the physical understanding of Mott transitions, opening opportunities for designing materials with tunable electronic properties.

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