Electron wave and quantum optics in graphene

Chakraborti, Himadri; Gorini, Cosimo; Knothe, Angelika; Liu, Ming-Hao; Makk, Péter; Parmentier, François D; Perconte, David; Richter, Klaus; Roulleau, Preden; Sacépé, Benjamin; Schönenberger, Christian; Yang, Wenmin

doi:10.1088/1361-648x/ad46bc

J. Phys.: Condens. Matter

2024

DOI: 10.1088/1361-648x/ad46bc

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Electron wave and quantum optics in graphene

Himadri Chakraborti,

Cosimo Gorini,

Angelika Knothe

et al.

Abstract: In the last decade, graphene has become an exciting platform for electron optical experiments, in some aspects superior to conventional two-dimensional electron gases (2DEGs). A major advantage, besides the ultra-large mobilities, is the fine control over the electrostatics,which gives the possibility of realising gap-less and compact p-n interfaces with high precision. The latter host non-trivial states, \eg, snake states in moderate magnetic fields, and serve as building blocks of complex electron i… Show more

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Cited by 4 publications

References 376 publications

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Electron beam-splitting effect with crossed zigzag graphene nanoribbons in high-spin metallic states

Sanz,

Giedke,

Sánchez-Portal

et al. 2024

APL Quantum

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Here, we analyze the electron transport properties of a device formed of two crossed graphene nanoribbons with zigzag edges (ZGNRs) in a spin state with total magnetization different from zero. While the ground state of ZGNRs has been shown to display antiferromagnetic ordering between the electrons at the edges, for wide ZGNRs—where the localized spin states at the edges are decoupled and the exchange interaction is close to zero—in the presence of relatively small magnetic fields, the ferromagnetic (FM) spin configuration can become the state of lowest energy due to the Zeeman effect. In these terms, by comparing the total energy of a periodic ZGNR as a function of the magnetization per unit cell, we obtain the FM-like solution of the lowest energy for the perfect ribbon, the corresponding FM-like configuration of the lowest energy for the four-terminal device formed of crossed ZGNRs, and the critical magnetic field needed to excite the system to this spin configuration. By performing transport calculations, we analyze the role of the distance between layers and the crossing angle of this device in the electrical conductance, at small gate voltages. The problem is approached employing the mean-field Hubbard Hamiltonian in combination with non-equilibrium Green’s functions. We find that ZGNR devices subject to transverse magnetic fields may acquire a high-spin configuration that ensures a metallic response and tunable beam-splitting properties, making this setting promising for studying electron quantum optics with single-electron excitations.

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Electron beam-splitting effect with crossed zigzag graphene nanoribbons in high-spin metallic states

Sanz,

Giedke,

Sánchez-Portal

et al. 2024

APL Quantum

View full text Add to dashboard Cite

show abstract

Steering internal and outgoing electron dynamics in bilayer graphene cavities by cavity design

Seemann,

Knothe,

Hentschel

2024

New J. Phys.

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Ballistic, gate-deﬁned devices in two-dimensional materials oﬀer a platform for electron optics phenomena inﬂuenced by the material’s properties and gate control. We study the ray trajectory dynamics of all-electronic, gate-deﬁned cavities in bilayer graphene to establish how distinct regimes of the internal and outgoing charge carrier dynamics can be tuned and optimized by the cavity shape, symmetry, and parameter choice, e.g., the band gap and the cavity orientation. In particular, we compare the dynamics of two cavity shapes, o’nigiri, and Lima¸con cavities, which fall into diﬀerent symmetry classes. We demonstrate that for stabilising regular, internal cavity modes, such as periodic and whispering gallery orbits, it is beneﬁcial to match the cavity shape to the bilayer graphene Fermi line contour. Conversely, a cavity of a diﬀerent symmetry than the material dispersion allows one to determine preferred emission directionalities in the emitted far-ﬁeld.

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Criterion for vanishing valley asymmetric transmission in dual-gated bilayer graphene

Wu,

Meng,

Zhang

et al. 2024

New J. Phys.

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Realizing valley asymmetric transmission(VAT) for incoming valley unpolarized Dirac carriers across an electrostatically modulated confinement potential(ECP) step, which is located at the interface of the unipolar ($n-n'$) junction in dual-gated Bernal-bilayer graphene(BBG), has caught growing attention because it provides a platform to study the valley polarizer. Such a junction, however, seems to preclude from supporting vanishing VAT. Based on the effective two-band Hamiltonian of BBG with wave matching approach, we demonstrate theoretically that VAT through the $n$/$ n'$ interface vanishes in the following conditions: (i) the disappearing electrostatically modulated interlayer potential difference(EPD), or (ii) the invariance condition of the sum or difference of ECPs and EPDs, which physically corresponds to the zero band offset of the conduction or valence band in the band alignment of $n-n'$ junction. Guided by this, it is worth mentioning that the we can derive simple, analytical valley-independent expressions for the reflection and transmission probabilities. We further find the appearance of the nearly vanishing VAT for the four-band model in bilayer graphene with 'Mexican hat'-like band. As a byproduct, we apply these findings to suggest the best design for the valley-dependent selection of momenta based on dual-gated BBG connected to two pristine BBG electrodes in which ECPs of the two outer regions are distinguishable and show that the sign of valley polarization can be switched via varying EPD. We expect our results can provide guidance for future device applications relying on ballistic and valley-selective transport.

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Electron wave and quantum optics in graphene

Cited by 4 publications

References 376 publications

Electron beam-splitting effect with crossed zigzag graphene nanoribbons in high-spin metallic states

Electron beam-splitting effect with crossed zigzag graphene nanoribbons in high-spin metallic states

Steering internal and outgoing electron dynamics in bilayer graphene cavities by cavity design

Criterion for vanishing valley asymmetric transmission in dual-gated bilayer graphene

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