Magnetic properties of Dirac fermions in a buckled honeycomb lattice

Tabert, C. J.; Ćarbotte, J. P.; Nicol, E. J.

doi:10.1103/physrevb.91.035423

Cited by 24 publications

(39 citation statements)

References 60 publications

(169 reference statements)

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“…Band-gap engineering may mitigate this problem: band gap may be switched on and off by strain [44]; alternatively, an external electric field applied in a direction perpendicular to the buckled lattice can induce charge imbalance between the sublattices, and open a band gap [44]. In addition, a variable perpendicular electric field can induce a phase transition from a topological insulator to a trivial band insulator, passing through a valley-spin polarized metal [45], and can also induce superconducting states when doped. A tunable quantum phase transition from a singlet chiral d + id'-wave pairing phase to a triplet f-wave phase could occur, provoking an increase in the superconducting critical temperature [46].…”

Section: Spin-orbit Coupling (Soc) Can Open a Band Gap At The Otherwimentioning

confidence: 99%

Emergent elemental two-dimensional materials beyond graphene

Zhang¹,

Rubio²,

Lay³

2017

J. Phys. D: Appl. Phys.

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Two-dimensional (2D) materials may offer the ultimate scaling beyond the 5 nm gate length.The difficulty of reliably opening a band gap in graphene has led to the search for alternative, semiconducting 2D materials. Emerging classes of elemental 2D materials stand out for their compatibility with existing technologies and/or for their diverse, tunable electronic structures.Among this group, black phosphorene has recently shown superior semiconductor performances. Silicene and germanene feature Dirac-type band dispersions, much like graphene. Calculations show that most group IV and group V elements have one or more stable 2D allotropes, with properties potentially suitable for electronic and optoelectronic applications. Here, we review the advances in these fascinating elemental 2D materials and discuss progress and challenges in their applications in future opto-and nano-electronic devices.

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Section: Spin-orbit Coupling (Soc) Can Open a Band Gap At The Otherwimentioning

confidence: 99%

Emergent elemental two-dimensional materials beyond graphene

Zhang¹,

Rubio²,

Lay³

2017

J. Phys. D: Appl. Phys.

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“…Moreover, graphene and the α-T 3 lattice both exhibit particlehole symmetry breaking under the influence of both modulations. Very recently, the Carbotte group has shown that a small asymmetry in the energy band can be very sensitive to magneto-optical excitation 56,57 . Therefore, we conclude that the combination of both modulations can be used as a tool to break the particle-hole symmetry for manipulation of the valley degree of freedom in optical devices.…”

Section: Discussionmentioning

confidence: 99%

Valley-polarized magnetoconductivity and particle-hole symmetry breaking in a periodically modulated α−T3 lattice

Islam

Dutta

2017

Phys. Rev. B

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We explore the transport properties of a periodically modulated α-T3 lattice in the presence of a perpendicular magnetic field. The effect of the Berry phase on electrical conductivity oscillation, socalled Weiss oscillation, caused by the modulation induced non-zero drift velocity of charge carriers is investigated. Employing linear response theory within the low temperature regime, we analyze Weiss oscillation as a function of the external magnetic field for both electrically and magnetically modulated α-T3 lattice numerically as well as analytically. The Berry phase makes this hexagonal lattice structure behave differently than other two-dimensional fermionic systems. It causes a significant valley polarization in magnetoconductivity. Most interestingly, the combined effect of both modulations breaks the particle-hole symmetry and causes a smooth transition from even (odd) to odd (even) filling fraction corresponding to the density of states peaks by means of the Berry phase.

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“…The results of Fig. 3(a), dashed curve, can be reduced to those of single-valley gapped graphene for ∆ h = 0 [26], irrespective of a factor of 2 due to valley degeneracy, and to those of gapped TIs [31]. However, for ∆ Ω > ∆ h = 0 only one surface must be considered, see Fig.…”

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confidence: 92%

Unconventional quantum Hall effect in Floquet topological insulators

Tahir

Vasilopoulos

Schwingenschlögl

2016

J. Phys.: Condens. Matter

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We study an unconventional quantum Hall effect for the surface states of ultrathin Floquet topological insulators in a perpendicular magnetic field. The resulting band structure is modified by photon dressing and the topological property is governed by the low-energy dynamics of a single surface. An exchange of symmetric and antisymmetric surface states occurs by reversing the light's polarization. We find a novel quantum Hall state in which the zeroth Landau level undergoes a phase transition from a trivial insulator state, with Hall conductivity σyx = 0 at zero Fermi energy, to a Hall insulator state with σyx = e 2 /2h. These findings open new possibilities for experimentally realizing nontrivial quantum states and unusual quantum Hall plateaux at (±1/2, ±3/2, ±5/2, ...)e 2 /h. In the regime of the integral quantum Hall effect (IQHE) for conventional, two-dimensional (2D) systems, e.g., in a GaAs/AlGaAs heterostructure, the Hall conductivity takes the values 2(n+1)e 2 /h = (2, 4, 6, ...) e 2 /h, where h is the Planck constant, e the electron charge, and n an integer. In graphene though the IQHE plateaux appear at 4(n + 1/2)e 2 /h = (±2, ±6, ±10, ...) e 2 /h [1], and the "half integer" aspect is hidden under the 4-fold degeneracy associated with the spin and valley degrees of freedom [2]. More recently, the IQHE has been assessed for silicene [3] and MoS 2 [4] in which the spinorbit interaction rearranges, as in 2D systems [5], the Landau levels (LLs) in two groups and the plateaux appear at integer values of e 2 /h due to a double degeneracy (±0, ±1, ±2, ±4, ±6, ...). In topological insulators (TIs) electrons on both top and bottom surfaces contribute to the Hall conductivity and its plateaux, due to the surface degeneracy, have heights 2(n + 1/2) e 2 /h = (±0, ±1, ±3, ±5, ...)e 2 /h [6-8]. Though the quest for a genuine "half-integer" QHE is long, a QHE like (n + 1/2) e 2 /h = (±0, ±1/2, ±3/2, ±5/2, ...) e 2 /h without any degeneracy prefactor, has not been observed. Then one wonders whether a "half-integer" QHE is possible in TIs by breaking their surface degeneracy.TIs More recently, the surface states of TIs driven by circularly polarized off-resonant light have become a subject of strong interest [17][18][19][20]. TIs driven by external timeperiodic perturbations are known as Floquet TIs (FTIs). * udo.schwingenschlogl@kaust.edu.sa For such systems it is convenient to use the Floquet theory [18]. In the appropriate frequency regime the offresonant light cannot generate real photon absorption or emission due to energy conservation. Accordingly, it does not directly excite electrons but instead modifies the electron band structure through second-order virtual-photon absorption processes. Averaged over time these processes result in an effective static alteration of the band structure. Illuminating, e.g., graphene or silicene with offresonant light generates a Haldane-type gap [21].Floquet bands were first realized in photonic crystals [22] and have been verified by recent experiments on the surface states of...

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Magnetic properties of Dirac fermions in a buckled honeycomb lattice

Cited by 24 publications

References 60 publications

Emergent elemental two-dimensional materials beyond graphene

Emergent elemental two-dimensional materials beyond graphene

Valley-polarized magnetoconductivity and particle-hole symmetry breaking in a periodically modulated α−T3 lattice

Unconventional quantum Hall effect in Floquet topological insulators

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