Epitaxial integration of TiO2 with Si(100) through a novel approach of oxidation of TiN/Si(100) epitaxial heterostructure

Control over the concurrent occurrence of structural (monoclinic to tetragonal) and electrical (insulator to the conductor) transitions presents a formidable challenge for VO 2 -based thin film devices. Speed, lifetime, and reliability of these devices can be significantly improved by utilizing solely electrical transition while eliminating structural transition. We design a novel strain-stabilized isostructural VO 2 epitaxial thin-film system where the electrical transition occurs without any observable structural transition. The thin-film heterostructures with a completely relaxed NiO buffer layer have been synthesized allowing complete control over strains in VO 2 films. The strain trapping in VO 2 thin films occurs below a critical thickness by arresting the formation of misfit dislocations. We discover the structural pinning of the monoclinic phase in (10 ± 1 nm) epitaxial VO 2 films due to bandgap changes throughout the whole temperature regime as the insulator-to-metal transition occurs. Using density functional theory, we calculate that the strain in monoclinic structure reduces the difference between long and short V-V bond-lengths (Δ V − V ) in monoclinic structures which leads to a systematic decrease in the electronic bandgap of VO 2 . This decrease in bandgap is additionally attributed to ferromagnetic ordering in the monoclinic phase to facilitate a Mott insulator without going through the structural transition.

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“…The magnetic properties were measured using a vibrating superconducting quantum interference device (SQUID) magnetometer 49–51 .…”

Section: Methodsmentioning

confidence: 99%

Electrical Transition in Isostructural VO2 Thin-Film Heterostructures

Moatti

Sachan

Cooper

et al. 2019

Sci Rep

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“…Thin film heterostructures were deposited using a KrF excimer laser with the frequency of 5 Hz and energy of 3.5 mJ/cm 2 . − The NiO layer was grown at 700 °C and 10 × 10 –4 Torr oxygen pressure, and the VO 2 film was deposited at 550 °C and 1.2 × 10 –2 Torr oxygen pressure . The vacuum-annealing procedure was performed at 1 × 10 –7 and 450 °C for 2 h.…”

Section: Methodsmentioning

confidence: 99%

Vacancy-Driven Robust Metallicity of Structurally Pinned Monoclinic Epitaxial VO₂ Thin Films

Moatti

Sachan

Gupta

et al. 2018

ACS Appl. Mater. Interfaces

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Vanadium dioxide (VO2) is a strongly correlated material with 3d electrons, which exhibits temperature-driven insulator-to-metal transition with a concurrent change in the crystal symmetry. Interestingly, even modest changes in stoichiometry-induced orbital occupancy dramatically affect the electrical conductivity of the system. Here, we report a successful transformation of epitaxial monoclinic VO2 thin films from a conventionally insulating to permanently metallic behavior by manipulating the electron correlations. These ultrathin (∼10 nm) epitaxial VO2 films were grown on NiO(111)/Al2O3(0001) pseudomorphically, where the large misfit between NiO and Al2O3 were fully relaxed by domain-matching epitaxy. Complete conversion from an insulator to permanent metallic phase is achieved through injecting oxygen vacancies (x ∼ 0.20 ± 0.02) into the VO2–x system via annealing under high vacuum (∼5 × 10–7 Torr) and increased temperature (450 °C). Systematic introduction of oxygen vacancies partially converts V4+ to V3+ and generates unpaired electron charges which result in the emergence of donor states near the Fermi level. Through the detailed study of the vibrational modes by Raman spectroscopy, hardening of the V–V vibrational modes and stabilization of V–V dimers are observed in vacuum-annealed VO2 films, providing conclusive evidence for stabilization of a monoclinic phase. This ultimately leads to convenient free-electron transport through the oxygen-deficient VO2–x thin films, resulting in metallic characteristics at room temperature. With these results, we propose a defect engineering pathway through the control of oxygen vacancies to tune electrical and optical properties in epitaxial monoclinic VO2.

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“…It is important to note that, tensile strain at the interface moderately increases the kinetic barrier for dislocation nucleation. Even though thermodynamically the h c is calculated at 15 nm, kinetically dislocations do not form up to a bit higher value due to enhanced dislocation nucleation barrier enforced by the tensile strain [18,24].…”

Section: Resultsmentioning

confidence: 96%

Mechanism of strain relaxation: key to control of structural and electronic transitions in VO₂ thin-films

Moatti

Sachan

Narayan

2019

Materials Research Letters

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VO 2 is a smart transition-metal oxide, which exhibits a tetragonal-to-monoclinic phase transition at ∼ 68°C. We report a case where both tetragonal and monoclinic phases exist in relaxed and strained domains, respectively, above the transition temperature. The epitaxial nucleation of these relaxed domains of VO 2 over the strained one occurs when the critical thickness criterion is met through the emergence of interfacial dislocations under domain-matching epitaxy paradigm. Below this critical thickness, the film isostructurally (across the transition temperature range) adopts a strained-monoclinic phase. Above the critical thickness, domains are structurally free to transform from tetragonal to monoclinic. IMPACT STATEMENT We studied formation and atomic-scale characterization of a novel heterostructure of relaxed (tetragonal/monoclinic) and unrelaxed (monoclinic) VO 2 phases. The monoclinic-to-tetragonal structural transition occurs at the critical thickness of ∼ 15 nm.

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Epitaxial integration of TiO2 with Si(100) through a novel approach of oxidation of TiN/Si(100) epitaxial heterostructure

Cited by 7 publications

References 24 publications

Electrical Transition in Isostructural VO2 Thin-Film Heterostructures

Electrical Transition in Isostructural VO2 Thin-Film Heterostructures

Vacancy-Driven Robust Metallicity of Structurally Pinned Monoclinic Epitaxial VO₂ Thin Films

Mechanism of strain relaxation: key to control of structural and electronic transitions in VO₂ thin-films

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Epitaxial integration of TiO2 with Si(100) through a novel approach of oxidation of TiN/Si(100) epitaxial heterostructure

Cited by 7 publications

References 24 publications

Electrical Transition in Isostructural VO2 Thin-Film Heterostructures

Electrical Transition in Isostructural VO2 Thin-Film Heterostructures

Vacancy-Driven Robust Metallicity of Structurally Pinned Monoclinic Epitaxial VO2 Thin Films

Mechanism of strain relaxation: key to control of structural and electronic transitions in VO2 thin-films

Contact Info

Product

Resources

About

Vacancy-Driven Robust Metallicity of Structurally Pinned Monoclinic Epitaxial VO₂ Thin Films

Mechanism of strain relaxation: key to control of structural and electronic transitions in VO₂ thin-films