Tuning the topological states in metal-organic bilayers

Lima, Felipe Crasto de; Ferreira, Gerson J.; Miwa, R. H.

doi:10.1103/physrevb.96.115426

Cited by 15 publications

(17 citation statements)

References 34 publications

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“…In a previous study 17 , we verified that the occupation of the kagome bands, as well as the localization of the non-trivial energy gaps in MOF/MOF interfaces, can be controlled by an external electric field. It is worth to pointing out that the energy bands responsible to the QAH phase are completely spin polarized and separated, with the magnetization out of the MOF plane.…”

Section: Quantum Anomalous Hall Effectsupporting

confidence: 64%

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Quantum anomalous Hall effect in metal-bis(dithiolene), magnetic properties, doping and interfacing graphene

Lima

Ferreira

Miwa

2018

Phys. Chem. Chem. Phys.

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The realization of the Quantum anomalous Hall effect (QAHE) in two dimensional (2D) metal organic frameworks (MOFs), (MC4S4)3 with M = Mn, Fe, Co, Ru and Rh, has been investigated based on a combination of first-principles calculations and tight binding models. Our analysis of the magnetic anisotropy energy (MAE) reveals that the out-of-plane (in-plane) magnetization is favored for M = Mn, Fe, and Ru (Co, and Rh). Therefore, we predict that the structural symmetry of (MC4S4)3 yields the QAHE only for M = Mn, Fe and Ru. Such a quantum anomalous Hall phase has been confirmed through the calculation of the Chern number, and examining the formation of topologically protected (metallic) edge states. Furthermore, we show that viable electron (n-type) doping of the MOFs can be used to place the Fermi level within the non-trivial energy gap; where we find that in (RuC4S4)3, in addition to the up-shift of the Fermi level, the MAE energy increases by 40%. Finally, we show that in MOF/graphene (vdW) interfaces, the Fermi level tuning can be done with an external electric field, which controls the charge transfer at the MOF/graphene interface, giving rise to switchable topologically protected edge currents in the MOFs.

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Section: Quantum Anomalous Hall Effectsupporting

confidence: 64%

“…Further molecular design has been done by building up multilayered systems by stacking MOFs [13][14][15][16] . Very recently, based on firstprinciples calculations, we have found that bilayer sys-tems of (MC 4 S 4 ) 3 , with M=Ni and Pt, present the Z 2metallic phase, where the edge states can be tuned by an EEF ⊥ 17 .…”

Section: Introductionmentioning

confidence: 99%

Quantum anomalous Hall effect in metal-bis(dithiolene), magnetic properties, doping and interfacing graphene

Lima

Ferreira

Miwa

2018

Phys. Chem. Chem. Phys.

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“…For instance, in (NiC 4 S 4 ) 3 bilayers (2ML), the stacking geometry is characterized by the alignment of sites X and Y of the different layers (2ML-XY), with X and Y = A, B, G, and H, as indicated in Fig. 1 In a previous study [26], we have found the 2ML-AA configuration to be the most stable. There, the calculations were performed using the non-local vdW-DF2 [38] correction to describe the vdW interactions.…”

Section: A Stacking Geometrymentioning

confidence: 92%

“…Recently, it has been proposed a bending strain perturbation approach to control spin currents in 2DTIs [29]. Meanwhile, ensuing research has shown a) Electronic mail: felipe.lima@ufu.br layer localization control of topological states by an applied external electric field in MOF bilayer nanoribbons [26] and bilayer graphene grain boundaries [30]. Furthermore, the exploration of van de Waals heterostructures allows for designed properties by combining the stacking of two-dimensional materials [31,32].…”

Section: Introductionmentioning

confidence: 99%

Layertronic control of topological states in multilayer metal-organic frameworks

Lima

Ferreira

Miwa

2019

The Journal of Chemical Physics

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We investigate the layer localization control of two-dimensional states in multilayer metal-organic frameworks (MOFs). For finite stackings of (NiC 4 S 4 ) 3 MOFs, the weak van der Waals coupling between adjacent layers leads to a Fermi level dependent distribution of the electronic states in the monolayers. Such distribution is reflected in the topological edge states of multilayer nanoribbons. Moreover, by applying an external electric field, parallel to the stacking direction, the spacial localization of the electronic states can be controlled for a chosen Fermi energy. This localization behavior is studied comparing density functional theory calculations with a kagome lattice tight-binding model. Furthermore, for infinite stacked nanoribbons, a new V-gutter Dirac state is found in the side surfaces, which allows anisotropic current control by tuning the Fermi energy. Our results can be immediately extended to other kagome MOFs with eclipsed stackings, introducing a new degree of freedom (layer localization) to materials design. arXiv:1903.03646v2 [cond-mat.mes-hall]

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“…Therefore, for zero external field ν = 0, the Hamiltonian commutes with τ x (which coincide with the M z symmetry operator), and the eigenstates reduce to the mirror symmetric and antisymmetric cases g m = ±1. Moreover, for ν = 0 we can still separate the Hamiltonian into two orthogonal subspaces defined by its pseudomirror symmetry [41]…”

Section: B Control Of Orbital-texture In Coupled Bilayermentioning

confidence: 99%

Orbital Pseudospin-Momentum Locking in Two-Dimensional Chiral Borophene

2019

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Recently, orbital-textures have been found in Rashba and topological insulator (TI) surface states as a result of the spin-orbit coupling (SOC). Here, we predict a px/py orbital texture, in linear dispersive Dirac bands, arising at the K/K' points of χ-h0 borophene chiral monolayer. Combining first-principles calculations with effective hamiltonians, we show that the orbital pseudospin has its direction locked with the momentum in a similar way as TIs' spin-textures. Additionally, considering a layer pseudospin degree of freedom, this lattice allows stackings of layers with equivalent or opposite chiralities. In turn, we show a control of the orbital textures and layer localization through the designed stacking and external electric field. For instance, for the opposite chirality stacking, the electric field allows for an on/off switch of the orbital-textured Dirac cone.

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Tuning the topological states in metal-organic bilayers

Cited by 15 publications

References 34 publications

Quantum anomalous Hall effect in metal-bis(dithiolene), magnetic properties, doping and interfacing graphene

Quantum anomalous Hall effect in metal-bis(dithiolene), magnetic properties, doping and interfacing graphene

Layertronic control of topological states in multilayer metal-organic frameworks

Orbital Pseudospin-Momentum Locking in Two-Dimensional Chiral Borophene

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