Out-of-plane interface dipoles and anti-hysteresis in graphene-strontium titanate hybrid transistor

Sahoo, Anindita; Nafday, Dhani; Paul, Tathagata; Ruiter, Roald; Roy, Arunesh; Mostovoy, Maxim; Banerjee, T.; Saha‐Dasgupta, Tanusri; Ghosh, Arindam

doi:10.1038/s41699-018-0055-5

Cited by 13 publications

(18 citation statements)

References 71 publications

(86 reference statements)

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“…19 In the rst case, this transition was explained by electrolyte insertion between graphene and the ferroelectric "compensating for anti-ferroelectric effects", while in the second it was "attributed to the dynamic response of interface screening charges that are activated by the combined effects of electric eld and temperature". It was then recognized that working in cleaner conditions is needed and a few years ago experiments were reported in vacuum in the range of 10 À3 to 10 À4 Pa. [20][21][22] Other precautions in terms of cleanness were undertaken, including thermal treatment. 1,23,24 However, the results were not concluding in all cases and it was acknowledged that even working in the above vacuum conditions, the inuence of chemisorbed OH À and H + cannot be ruled out.…”

Section: Introductionmentioning

confidence: 99%

“…1,23,24 However, the results were not concluding in all cases and it was acknowledged that even working in the above vacuum conditions, the inuence of chemisorbed OH À and H + cannot be ruled out. 22 The charge carrier density in 1 ML graphene is insufficient to screen a polarization exceeding a few tenths of C m À2 , 2,14 see also the evaluation a few paragraphs below. In addition to the above mentioned hypotheses, other extrinsic compensation mechanisms were proposed, such as charge transfer driven by electronegativity differences between outermost atoms from ferroelectrics and carbon, 25 direct interaction of graphene with defects, which modify carbon hybridization from sp 2 to sp 3 or charge injection into interfacial traps, 1 dynamic accumulation of oxygen vacancies near the interface, forming a layer with different dielectric constant, 26 charge trapping prevailing over ferroelectric effects, 6 "intrinsic bulk ferroelectric hysteresis in combination of an oxygen-decient surface layer", 20 O 2 /H 2 O redox couple intermediated by graphene charging.…”

Section: Introductionmentioning

confidence: 99%

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Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp² layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

et al. 2020

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp² layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

et al. 2020

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“…Further, antihysteresis in graphene square resistance, when back gated through STO has been reported by several groups and is an active area of research. 17 , 19 , 21 …”

Section: Introductionmentioning

confidence: 99%

Unveiling Temperature-Induced Structural Domains and Movement of Oxygen Vacancies in SrTiO₃ with Graphene

Chen

Duijnstee

et al. 2020

ACS Appl. Mater. Interfaces

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Heterointerfaces coupling complex oxides exhibit coexisting functional properties such as magnetism, superconductivity, and ferroelectricity, often absent in their individual constituent. SrTiO 3 (STO), a canonical band insulator, is an active constituent of such heterointerfaces. Temperature-, strain-, or mechanical stress-induced ferroelastic transition leads to the formation of narrow domains and domain walls in STO. Such ferroelastic domain walls have been studied using imaging or transport techniques and, often, the findings are influenced by the choice and interaction of the electrodes with STO. In this work, we use graphene as a unique platform to unveil the movement of oxygen vacancies and ferroelastic domain walls near the STO surface by studying the temperature and gate bias dependence of charge transport in graphene. By sweeping the back gate voltage, we observe antihysteresis in graphene typically observed in conventional ferroelectric oxides. Interestingly, we find features in antihysteresis that are related to the movement of domain walls and of oxygen vacancies in STO. We ascertain this by analyzing the time dependence of the graphene square resistance at different temperatures and gate bias. Density functional calculations estimate the surface polarization and formation energies of layer-dependent oxygen vacancies in STO. This corroborates quantitatively with the activation energies determined from the temperature dependence of the graphene square resistance. Introduction of a hexagonal boron nitride (hBN) layer, of varying thicknesses, between graphene and STO leads to a gradual disappearance of the observed features, implying the influence of the domain walls onto the potential landscape in graphene.

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“…The surface of STO has a broken inversion symmetry and is found to harbor surface dipoles where the oxygen atoms are displaced outwards . The strength of these surface dipole moments is calculated to be

P = - 13.89 normalμ normalC c {normalm}^{- 2}

which increases to

P = - 34.90 normalμ normalC c {normalm}^{- 2}

with the graphene layer . This electric field, pointing outwards from the substrate plane, originates from the surface dipoles in STO.…”

mentioning

confidence: 96%

“…Further, distinct from most other substrates on which charge and spin transport in graphene has been studied, the broken inversion symmetry at the surface of STO leads to Rashba spin orbit fields that can be tuned by an electric field . Recently it was demonstrated that electric dipoles, formed at the surface of STO, results in a large out of plane electric polarization that influences the charge transport in graphene . STO undergoes a ferroelastic transition changing from cubic ( a = 3.905 Å) to tetragonal symmetry (

c / a = 1.0056

) at T = 105 K .…”

mentioning

confidence: 99%

Temperature and Electric Field Dependence of Spin Relaxation in Graphene on SrTiO₃

Chen

Ruiter

Mathkar

et al. 2018

Physica Rapid Research Ltrs

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The theoretically predicted intrinsic spin relaxation time of up to 1 μs in graphene along with extremely high mobilities makes it a promising material in spintronics. Numerous experimental studies, however, find the spin lifetime in graphene to be several orders of magnitude below that theoretically predicted. Additionally, analyses of the spin relaxation mechanisms in graphene using conventional processes such as Elliot-Yaffet and D'yakonov-Perel' show a coexistence of both, with no clear dominance. Central to these experimental discrepancies is the role of the local environment including that of the underlying substrate. In this work, we use the electronically rich platform of SrTiO 3 with broken inversion symmetry and study spin transport in graphene in the presence of surface electric fields. We find spin relaxation time and length as large as 0.96 AE 0.03 ns and 4.1 AE 0.1 μm, respectively at 290 K in graphene, using non-local spin valve studies and find a non monotonous dependence with temperature, unlike that observed in other substrates. Analysis of the temperature dependence indicates the role of surface electric dipoles and electric field driven electronic and structural phase transitions unique to SrTiO 3 for spin transport and spin relaxation in graphene.Charge conduction and spin transport parameters in twodimensional graphene are strongly influenced by extrinsic factors related to their local environment. Extrinsic influences range from the specifics of the underlying substrate (suspended, encapsulated, or high dielectric constant), [1,2] the quality of the contacts [3,4] to spinorbit effects due to adatoms. [5][6][7] Despite significant improvements either on enhancing the graphene quality including encapsulation on an atomically flat two dimensional hexagonal Boron Nitride (hBN) substrate or by resolving extrinsic influences, the experimentally measured spin lifetime in graphene is orders of magnitude smaller than theoretically predicted. [8][9][10][11][12][13] Furthermore, conventional spin relaxation mechanisms such as Elliot-Yaffet and D'yakonov-Perel' fail to unambiguously explain the nature and dominance of the spin dephasing processes in graphene on different substrates. [5][6][7][8]14] Spin dephasing can originate from a multitude of effects such as flexural distortions, ripples, local magnetic moments, to name a few, but understanding of their precise micoroscopic mechanism still remains elusive. [5][6][7] In this context SrTiO 3 (STO) lends itself as an interesting choice of substrate to study spin relaxation mechanisms in graphene. [15] STO has an atomically flat surface, similar to that of hBN, with roughness of 90-150 pm and no dangling bonds. However, unlike hBN, STO is electronically versatile. This stems from the remarkably large dielectric constant (e r ) of 300 at room temperature that increases non-linearly to >20 000 at 4 K. [16] Further, distinct from most other substrates on which charge and spin transport in graphene has been studied, the broken inversion symmetry at the sur...

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Out-of-plane interface dipoles and anti-hysteresis in graphene-strontium titanate hybrid transistor

Cited by 13 publications

References 71 publications

Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp² layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp² layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

Unveiling Temperature-Induced Structural Domains and Movement of Oxygen Vacancies in SrTiO₃ with Graphene

Temperature and Electric Field Dependence of Spin Relaxation in Graphene on SrTiO₃

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Out-of-plane interface dipoles and anti-hysteresis in graphene-strontium titanate hybrid transistor

Cited by 13 publications

References 71 publications

Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp2 layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp2 layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

Unveiling Temperature-Induced Structural Domains and Movement of Oxygen Vacancies in SrTiO3 with Graphene

Temperature and Electric Field Dependence of Spin Relaxation in Graphene on SrTiO3

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Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp² layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

Resistance hysteresis correlated with synchrotron radiation surface studies in atomic sp² layers of carbon synthesized on ferroelectric (001) lead zirconate titanate in an ultrahigh vacuum

Unveiling Temperature-Induced Structural Domains and Movement of Oxygen Vacancies in SrTiO₃ with Graphene

Temperature and Electric Field Dependence of Spin Relaxation in Graphene on SrTiO₃