Electrical properties of ZnO–BaTiO3–ZnO heterostructures with asymmetric interface charge distribution

Voora, V. M.; Hofmann, Tino; Brandt, M.; Lorenz, Michael; Ashkenov, N.; Grundmann, Marius; Schubert, M.

doi:10.1063/1.3211914

Cited by 23 publications

(12 citation statements)

References 25 publications

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“…Brief biasing by short voltage pulses here switch the bijunction heterostructure into situations ͑i͒ or ͑ii͒ and in which the heterostructure static series resistance is slightly different, e.g., at a given "read" voltage of 1 V. Bistable switching operation of this heterostructure was presented recently. 59 A similar switching behavior was observed previously in metal-ferroelectric-metal heterostruc layer dielectric continuum model calculations augmented by parallel circuits of diode-resistance pairs that such hysteresis offset can occur due to asymmetric resistance changes. In their series model, two pairs of antiparallel oriented diodes with two different resistances mimic the effect of different leakage currents within the ferroelectric layer over the metal interface barriers into the metal contacts.…”

Section: Single-layer F: Experimentssupporting

confidence: 58%

“…11 In our heterostructures, the diodelike behavior originates from the variation in the depletion layers and the ferroelectric polarization. 59 The PFP heterostructures discussed in our work possess potential for new ferroelectric-semiconductor thin-film device applications.…”

Section: Single-layer F: Experimentsmentioning

confidence: 99%

“…Structural, optical, and electrical analysis were performed as described previously. 12,[54][55][56][57][58][59] The ZnO layers are n-type conductive, with free electron concentration N c between 1 ϫ 10 16 -1 ϫ 10 17 cm −3 . Net donor densities were determined by electrical Hall effect and Infrared Ellipsometry characterization.…”

Section: Experiments a Sample Preparationmentioning

confidence: 99%

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Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures

et al. 2010

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M.; Hofmann, Tino; Brandt, M.; Lorenz, M.; Grundmann, M.; Ashkenov, N.; Schmidt, H.; Ianno, Natale J.; and Schubert, Mathias, "Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures" (2010 We present a dielectric continuum model approach for studying the electrical polarization properties of interface polarization coupled BaTiO 3 , BaTiO 3 -ZnO, and ZnO-BaTiO 3 -ZnO thin-film structures consisting of several hundred nanometer thick layers. Our model augments the effects of electric field driven switchable polarization and depletion layer formation with spontaneous interface polarization coupling. Wurtzite-structure ͑piezoelectric͒ n-type ZnO and perovskite-structure ͑ferroelectric͒ highly insulating BaTiO 3 layers were prepared and investigated. The coupling between the nonswitchable spontaneous polarization of ZnO and the electrically switchable spontaneous polarization of BaTiO 3 causes strong asymmetric polarization hysteresis behavior. The n-type ZnO reveals hysteresis-dependent capacitance variations upon formation of depletion layers at the ZnO/BTO interfaces. We obtain a very good agreement between our model generated data and our experiment. Our model approach allows for derivation of the amount and orientation of the spontaneous polarization of the piezoelectric constituents and can be generalized toward multiple-layer piezoelectricsemiconductor ferroelectric heterostructures. We identify interface polarization coupled triple-layer ZnO-BTOZnO heterostructures as two-terminal unipolar ferroelectric Bi-junction transistor for use in memory storage.

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Section: Single-layer F: Experimentssupporting

confidence: 58%

Section: Single-layer F: Experimentsmentioning

confidence: 99%

Section: Experiments a Sample Preparationmentioning

confidence: 99%

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Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures

et al. 2010

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“…30 Transition metals make a multiferroic semiconductor. In particular, Ba-doped ZnO material has not been largely studied, since just ZnO/BaTiO 3 heterojunction [31][32][33][34] and BaO/ZnO interfaces 35 have been recently investigated. The most common atoms inserting in the ZnO structure are N, 36,37 Pd, 37 Mg, 38 Gd 39 atoms and lanthanide metals.…”

Section: Introductionmentioning

confidence: 99%

Ba-DOPED ZnO MATERIALS: A DFT SIMULATION TO INVESTIGATE THE DOPING EFFECT ON FERROELECTRICITY

Lacerda¹,

Lázaro²

2016

Química Nova

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publicado na web em 18/02/2015ZnO is a semiconductor material largely employed in the development of several electronic and optical devices due to its unique electronic, optical, piezo-, ferroelectric and structural properties. This study evaluates the properties of Ba-doped wurtzite-ZnO using quantum mechanical simulations based on the Density Functional Theory (DFT) allied to hybrid functional B3LYP. The Badoping caused increase in lattice parameters and slight distortions at the unit cell angle in a wurtzite structure. In addition, the doping process presented decrease in the band-gap (E g ) at low percentages suggesting band-gap engineering. For low doping amounts, the wavelength characteristic was observed in the visible range; whereas, for middle and high doping amounts, the wavelength belongs to the Ultraviolet range. The Ba atoms also influence the ferroelectric property, which is improved linearly with the doping amount, except for doping at 100% or wurtzite-BaO. The ferroelectric results indicate the ZnO:Ba is an strong option to replace perovskite materials in ferroelectric and flash-type memory devices.

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“…[14][15][16][17] Coupling between the piezoelectric ZnO and the ferroelectric BaTiO 3 may cause bistable ferroelectric polarization orientation. [18][19][20][21][22] The piezoelectric ZnO has an inherent polarization which is difficult to reverse using an electric eld, but the polarization of ferroelectric BaTiO 3 can be reversed in experiments. The parallel or antiparallel polarizations of ZnO and BaTiO 3 may lead to intrinsic asymmetric ferroelectricity in the ZnO/BaTiO 3 superlattice which is similar to that found in tricolor superlattices.…”

Section: Introductionmentioning

confidence: 99%

Intrinsic asymmetric ferroelectricity induced giant electroresistance in ZnO/BaTiO₃ superlattice

et al. 2021

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Electrical properties of ZnO–BaTiO3–ZnO heterostructures with asymmetric interface charge distribution

Cited by 23 publications

References 25 publications

Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures

Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures

Ba-DOPED ZnO MATERIALS: A DFT SIMULATION TO INVESTIGATE THE DOPING EFFECT ON FERROELECTRICITY

Intrinsic asymmetric ferroelectricity induced giant electroresistance in ZnO/BaTiO₃ superlattice

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Electrical properties of ZnO–BaTiO3–ZnO heterostructures with asymmetric interface charge distribution

Cited by 23 publications

References 25 publications

Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures

Interface polarization coupling in piezoelectric-semiconductor ferroelectric heterostructures

Ba-DOPED ZnO MATERIALS: A DFT SIMULATION TO INVESTIGATE THE DOPING EFFECT ON FERROELECTRICITY

Intrinsic asymmetric ferroelectricity induced giant electroresistance in ZnO/BaTiO3 superlattice

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Intrinsic asymmetric ferroelectricity induced giant electroresistance in ZnO/BaTiO₃ superlattice