Tunable Superlattice in Graphene To Control the Number of Dirac Points

Dubey, Sudipta; Singh, Vibhor; Bhat, Ajay K.; Parikh, Pritesh; Grover, Sameer; Sensarma, Rajdeep; Tripathi, Vikram; Sengupta, K.; Deshmukh, Mandar M.

doi:10.1021/nl4006029

Cited by 84 publications

(89 citation statements)

References 48 publications

(83 reference statements)

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“…This stands in contrast to the argumentation of Ref. [28], where a similar device with an even higher number of top gate stripes was investigated. Our calculations for a fully phase coherent system of N TG top gate stripes yield growing of resistance peaks due to the formation of new touching points of valence and conductance band as the band structure gets folded, giving rise to the opening of small energy band gaps.…”

Section: Towards Superlatticescontrasting

confidence: 82%

“…We focus our research on locally gated graphene with varying number of bipolar barriers and different spacing in order to characterize the impact of changing parameters on the resistance of the monolayer. A recent publication on a similar lateral multibarrier setup [28] attributes the occurring resonant behavior of the resistance in the bipolar regime to a superlattice effect in the lowdiffusive limit, even though the experimental elastic mean free path does not exceed one lattice period. We reproduce the reported resonant features and provide extended data for varying experimental parameters that can be explained within a consistent Fabry-Pérot resonance model, without resorting to a superlattice effect.…”

Section: Introductionmentioning

confidence: 99%

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Towards superlattices: Lateral bipolar multibarriers in graphene

et al. 2014

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We report on transport properties of monolayer graphene with a laterally modulated potential profile, employing striped top gate electrodes with spacings of 100 to 200 nm. Tuning of top and back gate voltages gives rise to local charge carrier density disparities, enabling the investigation of transport properties either in the unipolar (nn ) or the bipolar (np ) regime. In the latter, pronounced single-and multibarrier Fabry-Pérot (FP) resonances occur. We present measurements of different devices with different numbers of top gate stripes and spacings. The data are highly consistent with a phase coherent ballistic tight-binding calculation and quantum capacitance model, whereas a superlattice effect and modification of band structure can be excluded.

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Section: Towards Superlatticescontrasting

confidence: 82%

Section: Introductionmentioning

confidence: 99%

Towards superlattices: Lateral bipolar multibarriers in graphene

et al. 2014

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“…The ability to create abrupt (∼ 10 nm) tunable barriers in graphene allows new aspects to be explored. In addition, new physics, due to the role of crossed electric and magnetic field, that cannot be seen in conventional 2DEGS can be studied in SL structures based on graphene.In this letter, we study magneto transport in an electrostatically defined 1D lateral SL in graphene [13]. In our device we apply a perpendicular magnetic field and periodically modulate the charge carrier density in adjacent "ribbons" of graphene, tuning from an array of p-p' (or n-n' ) to an array of p-n' junctions.…”

mentioning

confidence: 99%

“…The geometric width of each top-gates is ∼ 30 nm and they have a period of λ = 150 nm. The effective electrostatic width of the top-gates felt by the charge carriers in graphene is larger due to the finite thickness of the top-gate dielectric [13] (details in Section VII of Supplemental Material).In our device, graphene consists of two alternating regions -one where the charge carrier density is controlled only by the back-gate (BG region); and the other where the charge carrier density is controlled by both the topgate and the back-gate (TG region). The difference in charge carrier density between BG and TG regions gives rise to a SL whose amplitude (V 0 ) is controlled by V bg and…”

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Tuning equilibration of quantum Hall edge states in graphene – Role of crossed electric and magnetic fields

Dubey

Deshmukh

2016

Solid State Communications

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We probe quantum Hall effect in a tunable 1-D lateral superlattice (SL) in graphene created using electrostatic gates. Lack of equilibration is observed along edge states formed by electrostatic gates inside the superlattice. We create strong local electric field at the interface of regions of different charge densities. Crossed electric and magnetic fields modify the wavefunction of the Landau Levels (LLs) -a phenomenon unique to graphene. In the region of copropagating electrons and holes at the interface, the electric field is high enough to modify the Landau levels resulting in increased scattering that tunes equilibration of edge states and this results in large longitudinal resistance.Magnetotransport across one-dimensional superlattice (SL) had been studied in two-dimensional electron gas in semiconductor heterostructures (2DEGS) [1][2][3][4][5][6], reporting dissipationless transport across high potential barriers [1] and magnetic commensurability oscillations in longitudinal resistance [3]. The motivation was to study various competing length scales and energy scales between tunable SL potential and quantum Hall system. Graphene offers the advantage of large cyclotron gap allowing quantum Hall effect to be observed at room temperature [7][8][9]. Substrate induced SL in graphene in the presence of magnetic field led to the experimental observation of Hofstadter butterfly physics [10][11][12]. The ability to create abrupt (∼ 10 nm) tunable barriers in graphene allows new aspects to be explored. In addition, new physics, due to the role of crossed electric and magnetic field, that cannot be seen in conventional 2DEGS can be studied in SL structures based on graphene.In this letter, we study magneto transport in an electrostatically defined 1D lateral SL in graphene [13]. In our device we apply a perpendicular magnetic field and periodically modulate the charge carrier density in adjacent "ribbons" of graphene, tuning from an array of p-p' (or n-n' ) to an array of p-n' junctions. Changing the magnetic field allows us to vary l B relative to λ; and changing the gate voltage allows us to tune the SL potential strength relative to LL spacing. The relative abruptness, bipolarity of charge carriers, large modulation and unequally spaced LLs distinguishes the present work from the previous work on 1D SL using 2DEGS systems [1][2][3][4]14].Apart from the length scales, we also study the energy scales involved. The competition between SL amplitude (V 0 ) and LL spacing (hω c , whereh = h/2π, h being the Planck's constant, and ω c is the cyclotron frequency) gives rise to three regimes. When V 0 >>hω c , SL effect dominates giving rise to extra Dirac points [15]. In the other extreme when V 0 <

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When 2D Materials Meet Molecules: Opportunities and Challenges of Hybrid Organic/Inorganic van der Waals Heterostructures

2018

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van der Waals heterostructures, composed of vertically stacked inorganic 2D materials, represent an ideal platform to demonstrate novel device architectures and to fabricate on-demand materials. The incorporation of organic molecules within these systems holds an immense potential, since, while nature offers a finite number of 2D materials, an almost unlimited variety of molecules can be designed and synthesized with predictable functionalities. The possibilities offered by systems in which continuous molecular layers are interfaced with inorganic 2D materials to form hybrid organic/inorganic van der Waals heterostructures are emphasized. Similar to their inorganic counterpart, the hybrid structures have been exploited to put forward novel device architectures, such as antiambipolar transistors and barristors. Moreover, specific molecular groups can be employed to modify intrinsic properties and confer new capabilities to 2D materials. In particular, it is highlighted how molecular self-assembly at the surface of 2D materials can be mastered to achieve precise control over position and density of (molecular) functional groups, paving the way for a new class of hybrid functional materials whose final properties can be selected by careful molecular design.

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Tunable Superlattice in Graphene To Control the Number of Dirac Points

Cited by 84 publications

References 48 publications

Towards superlattices: Lateral bipolar multibarriers in graphene

Towards superlattices: Lateral bipolar multibarriers in graphene

Tuning equilibration of quantum Hall edge states in graphene – Role of crossed electric and magnetic fields

When 2D Materials Meet Molecules: Opportunities and Challenges of Hybrid Organic/Inorganic van der Waals Heterostructures

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