Si Young Choi scite author profile

Phase transitions in correlated materials can be manipulated at the nanoscale to yield emergent functional properties, promising new paradigms for nanoelectronics and nanophotonics. Vanadium dioxide (VO), an archetypal correlated material, exhibits a metal-insulator transition (MIT) above room temperature. At the thicknesses required for heterostructure applications, such as an optical modulator discussed here, the strain state of VO largely determines the MIT dynamics critical to the device performance. We develop an approach to control the MIT dynamics in epitaxial VO films by employing an intermediate template layer with large lattice mismatch to relieve the interfacial lattice constraints, contrary to conventional thin film epitaxy that favors lattice match between the substrate and the growing film. A combination of phase-field simulation, in situ real-time nanoscale imaging, and electrical measurements reveals robust undisturbed MIT dynamics even at preexisting structural domain boundaries and significantly sharpened MIT in the templated VO films. Utilizing the sharp MIT, we demonstrate a fast, electrically switchable optical waveguide. This study offers unconventional design principles for heteroepitaxial correlated materials, as well as novel insight into their nanoscale phase transitions.

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Unleashing the Full Potential of Magnetoelectric Coupling in Film Heterostructures

Palneedi

Maurya

Kim

et al. 2017

Advanced Materials

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A record-high, near-theoretical intrinsic magnetoelectric (ME) coupling of 7 V cm Oe is achieved in a heterostructure of piezoelectric Pb(Zr,Ti)O (PZT) film deposited on magnetostrictive Metglas (FeBSi). The anchor-like, nanostructured interface between PZT and Metglas, improved crystallinity of PZT by laser annealing, and optimum volume of crystalline PZT are found to be the key factors in realizing such a giant strain-mediated ME coupling.

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Assessment of Strain-Generated Oxygen Vacancies Using SrTiO₃ Bicrystals

Choi¹,

Kim²,

Choi³

et al. 2015

Nano Lett.

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Atomic-scale defects strongly influence the electrical and optical properties of materials, and their impact can be more pronounced in localized dimensions. Here, we directly demonstrate that strain triggers the formation of oxygen vacancies in complex oxides by examining the tilt boundary of SrTiO3 bicrystals. Through transmission electron microscopy and electron energy loss spectroscopy, we identify strains along the tilt boundary and oxygen vacancies in the strain-imposed regions between dislocation cores. First-principles calculations support that strains, irrespective of their type or sign, lower the formation energy of oxygen vacancies, thereby enhancing vacancy formation. Finally, current-voltage measurements confirm that such oxygen vacancies at the strained boundary result in a decrease of the nonlinearity of the I-V curve as well as the resistivity. Our results strongly indicate that oxygen vacancies are preferentially formed and are segregated at the regions where strains accumulate, such as heterogeneous interfaces and grain boundaries.

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Si Young Choi

Ubiquitous magneto-mechano-electric generator

Writing monolithic integrated circuits on a two-dimensional semiconductor with a scanning light probe

Sharpened VO₂ Phase Transition via Controlled Release of Epitaxial Strain

Unleashing the Full Potential of Magnetoelectric Coupling in Film Heterostructures

Assessment of Strain-Generated Oxygen Vacancies Using SrTiO₃ Bicrystals

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Si Young Choi

Ubiquitous magneto-mechano-electric generator

Writing monolithic integrated circuits on a two-dimensional semiconductor with a scanning light probe

Sharpened VO2 Phase Transition via Controlled Release of Epitaxial Strain

Unleashing the Full Potential of Magnetoelectric Coupling in Film Heterostructures

Assessment of Strain-Generated Oxygen Vacancies Using SrTiO3 Bicrystals

Contact Info

Product

Resources

About

Sharpened VO₂ Phase Transition via Controlled Release of Epitaxial Strain

Assessment of Strain-Generated Oxygen Vacancies Using SrTiO₃ Bicrystals