Gate-Tunable Band Structure of the 
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 Interface

Smink, A. E. M.; Boer, J. C C. de; Stehno, Martin; Brinkman, Alexander; Wiel, Wilfred G. van der; Hilgenkamp, H.

doi:10.1103/physrevlett.118.106401

Cited by 75 publications

(133 citation statements)

References 48 publications

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“…The effects of gating have not been reported; however, one may infer from Fig. 4(a) that if the strain were to relax with increasing n 2D , the slope above the transition would be negative, as found in some experiments [15][16][17]. Figure 4(e) shows that the inclusion of intra-atomic interactions has a small quantitative effect on n 1xy , but does not change qualitative features of the transition.…”

mentioning

confidence: 78%

“…From the form ofĤ U [Eq. (15)], it is clear that minimization of the intra-orbital Coulomb energy favors a spreading-out of charge between orbitals if U 0 and J are large, and the collapse of charge into a single orbital type if U is large. Indeed, we find that our calculations favor occupation of d xy orbitals over d xz and d yz orbitals when J < U 0 /5, and favor occupation of multiple orbital types when J > U 0 /5.…”

Section: Coulomb Potentialmentioning

confidence: 99%

“…While there is general agreement that the sensitivity to doping is connected to an observed Lifshitz transition [5, 14-17] between a single occupied band at low density and multiple occupied bands at high density [6,[17][18][19][20][21][22][23][24], the mechanism by which this transition happens is not established.Density functional theory (DFT), while instrumental in establishing fundamental interface properties [25][26][27][28], finds electron densities that are an order of magnitude larger than the Lifshitz transition density n L ∼ 0.02-0.05 electrons per 2D unit cell, and cannot easily be tuned through the transition. Schrödinger-Poisson calculations, for which n 2D can be continuously tuned, persistently find multiple occupied bands even for n 2D n L [5,15,[29][30][31]. Indeed, we showed previously that, because of STO is close to a ferroelectric (FE) quantum critical point [32], electrons become deconfined from an ideal interface as n 2D → 0, and form a dilute quasi-threedimensional (quasi-3D) gas extending far into the STO substrate [33].…”

mentioning

confidence: 99%

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Possible flexoelectric origin of the Lifshitz transition in LaAlO3/SrTiO3 interfaces

Raslan

Atkinson

2018

Phys. Rev. B

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Multiple experiments have observed a sharp transition in the band structure of LaAlO3/SrTiO3 (001) interfaces as a function of applied gate voltage. This Lifshitz transition, between a single occupied band at low electron density and multiple occupied bands at high density, is remarkable for its abruptness. In this work, we propose a mechanism by which such a transition might happen. We show via numerical modeling that the simultaneous coupling of the dielectric polarization to the interfacial strain ("electrostrictive coupling") and strain gradient ("flexoelectric coupling") generates a thin polarized layer whose direction reverses at a critical density. The Lifshitz transition occurs concomitantly with the polarization reversal and is first-order at T = 0. A secondary Lifshitz transition, in which electrons spread out into semiclassical tails, occurs at a higher density.LaAlO 3 (LAO) and SrTiO 3 (STO) are band insulators; however, when four or more monolayers of LAO are grown on top of a STO substrate, a mobile twodimensional electron gas (2DEG) forms on the STO side of the interface [1, 2]. One compelling feature of these interfaces is that the character of the 2DEG changes dramatically with the application of a gate voltage. Indeed, for (001) interfaces there is a narrow doping range over which the superconducting transition temperature [3][4][5][6][7], the spin-orbit coupling [7-10], and the metamagnetic response [11] change by an order of magnitude. Furthermore, the superconducting gap and resistive transition appear at different temperatures at low electron densities, n 2D , but track each other closely at high n 2D [12]. This qualitative distinction between low and high doping has also been seen in quantum dot transport experiments, which reveal a crossover from attractive to repulsive pairing interactions with increasing n 2D [13]. While there is general agreement that the sensitivity to doping is connected to an observed Lifshitz transition [5, 14-17] between a single occupied band at low density and multiple occupied bands at high density [6,[17][18][19][20][21][22][23][24], the mechanism by which this transition happens is not established.Density functional theory (DFT), while instrumental in establishing fundamental interface properties [25][26][27][28], finds electron densities that are an order of magnitude larger than the Lifshitz transition density n L ∼ 0.02-0.05 electrons per 2D unit cell, and cannot easily be tuned through the transition. Schrödinger-Poisson calculations, for which n 2D can be continuously tuned, persistently find multiple occupied bands even for n 2D n L [5,15,[29][30][31]. Indeed, we showed previously that, because of STO is close to a ferroelectric (FE) quantum critical point [32], electrons become deconfined from an ideal interface as n 2D → 0, and form a dilute quasi-threedimensional (quasi-3D) gas extending far into the STO substrate [33]. This result is incompatible with experiments and raises the question, why is only a single band occupied at low n 2D ? Furthermore, t...

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mentioning

confidence: 78%

Section: Coulomb Potentialmentioning

confidence: 99%

mentioning

confidence: 99%

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Possible flexoelectric origin of the Lifshitz transition in LaAlO3/SrTiO3 interfaces

Raslan

Atkinson

2018

Phys. Rev. B

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“…According to our analysis one can formulate two conditions which have to be met in order to observe the characteristic domelike shape driven by the inter-subband pairing: (i) the lack of the inversion symmetry and (ii) the energetic proximity of the bands between which the pairing appears. Both requirements are met in the LaAlO 3 /SrTiO 3 interface: (i) the calculations for the conduction band at LaAlO 3 /SrTiO 3 interface based on the Poisson equation demonstrate that the confinement in the z-direction at the interface has a shape of the triangular quantum well 34,41,42 , which leads to the lack of the inversion symmetry; (ii) the tight-binding model for the LaAlO 3 /SrTiO 3 structure reveals the presence of three bands two of which (d XY /d Y Z and d Y Z /d XZ ) have relatively similar Fermi surfaces just above the Lifshitz transition what makes the intersubband pairing between them possible 30 . Nevertheless, this proposal still needs a detailed theoretical analysis in a more realistic model with all three d XY , d XZ , d Y Z orbitals, and the influence of the spin-orbit coupling, included.…”

Section: Discussion In the Context Of The Lao/sto Interfacementioning

confidence: 99%

Superconducting dome in doped 2D superconductors with broken inversion symmetry

Wójcik

Nowak

Zegrodnik

2020

Physica E: Low-dimensional Systems and Nanostructures

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We analyze an unconventional inter-subband paired phase in a 2D doped superconductor considering both systems with the inversion symmetry and with the inversion symmetry broken. We find that for a centro-symmetric system the inter-subband pairing can appear in the high concentration regime when the repulsive Coulomb interaction leads to the nearly degenerate symmetric and antisymmetric state. We discuss in detail the mutual competition between the intra-and inter-subband paired phase. For systems with broken inversion symmetry, we find that the critical temperature has a characteristic domelike shape as a function of the asymmetry parameter, which is explained as resulting form the inter-subbband pairing. This results is discussed in the context of the domelike shape of Tc in the LaAlO3/SrTiO3 interface.

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“…This led to proposals to base the phase diagram on the sheet conductivity [24][25][26][27], which also does not provide a universal result. Almost all these experiments were done in a backgate geometry, whereas topgating has a different effect on carrier mobility [28][29][30] and on the band structure [31]. This difference is due to the opposite direction of the applied electric field, resulting in a disparate effect on the shape of the confining 2 potential well.…”

mentioning

confidence: 99%

Correlation between superconductivity, band filling, and electron confinement at the LaAlO3/SrTiO3 interface

Smink¹,

Stehno²,

Boer³

et al. 2018

Phys. Rev. B

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By combined top-and backgating, we explore the correlation of superconductivity with band filling and electron confinement at the LaAlO 3 -SrTiO 3 interface. We find that the top-and backgate voltages have distinctly different effects on the superconducting critical temperature, implying that the confining potential well has a profound effect on superconductivity. We investigate the origin of this behavior by comparing the gate-dependence of T c to the corresponding evolution of the band filling with gate voltage. For several backgate voltages, we observe maximum T c to consistently coincide with a kink in tuning the band filling for high topgate voltage. Self-consistent Schrödinger-Poisson calculations relate this kink to a Lifshitz transition of the second d xy subband. These results establish a major role for confinement-induced subbands in the phase diagram of SrTiO 3 surface states, and establish gating as a means to control the relative energy of these states.

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Gate-Tunable Band Structure of the LaAlO3−SrTiO3 Interface

Cited by 75 publications

References 48 publications

Possible flexoelectric origin of the Lifshitz transition in LaAlO3/SrTiO3 interfaces

Possible flexoelectric origin of the Lifshitz transition in LaAlO3/SrTiO3 interfaces

Superconducting dome in doped 2D superconductors with broken inversion symmetry

Correlation between superconductivity, band filling, and electron confinement at the LaAlO3/SrTiO3 interface

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