Landau quantized dynamics and spectra for group-VI dichalcogenides, including a model quantum wire

Horing, Norman J. M.

doi:10.1063/1.4986221

Cited by 15 publications

(14 citation statements)

References 11 publications

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“…where n ≥ 1, u = a l t/ ≃ 0.66 × 10 6 m/s, see Table 1, and E w is defined in Eq. (31). The quantity 1/m * = u 2 /E w is the inverse of the energy effective mass of electron at the bottoms of conduction bands.…”

Section: E Group-vi Dichalogenides: Parabolic Bands Approximationmentioning

confidence: 99%

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Theory of Friedel oscillations in monolayer graphene and group-VI dichalcogenides in a magnetic field

Rusin

Zawadzki

2018

Phys. Rev. B

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Friedel oscillations (FO) of electron density caused by a delta-like neutral impurity in twodimensional (2D) systems in a magnetic field are calculated. Three 2D cases are considered: free electron gas, monolayer graphene and group-VI dichalcogenides. An exact form of the renormalized Green's function is used in the calculations, as obtained by a summation of the infinite Dyson series and regularization procedure. Final results are valid for large ranges of potential strengths V0, electron densities ne, magnetic fields B and distances from the impurity r. Realistic models for the impurities are used. The first FO of induced density in WS2 are described by the relation ∆n(r) ∝ sin(2πr/TF O)/r 2 , where TF O ∝ 1/ √ EF . For weak impurity potentials, the amplitudes of FO are proportional to V0. For attractive potentials and high fields the total electron density remains positive for all r. On the other hand, for low fields, repulsive potentials and small r, the total electron density may become negative, so that many-body effects should be taken into account.

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Section: E Group-vi Dichalogenides: Parabolic Bands Approximationmentioning

confidence: 99%

“…There is N n = 2E n (E n − E w ), where E w and E n are defined in Eqs. (31) and (33), respectively. For n = 0 there is where Ψ(a, c; t) is the second solution of the confluent hypergeometric equation [60], and W κ,µ (t) is the Whittaker function.…”

Section: Appendix A: Green's Function In Group-vi Dichalcogenidesmentioning

confidence: 99%

Theory of Friedel oscillations in monolayer graphene and group-VI dichalcogenides in a magnetic field

Rusin

Zawadzki

2018

Phys. Rev. B

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“…As indicated above, our approach to the determination of the role of a quantizing magnetic field in the entropy of charge carriers of the Group VI Dichalcogenides in the low energy regime (in which their Hamiltonian is "Dirac-like" with energy proportional to momentum) is undertaken using the retarded Green's function; In earlier work 15 , the associated Landau-quantized Green's function matrix was derived with full account of its pseudospin-1/2 and spin-1/2 features in the presence of a high magnetic field; and the pertinent diagonal elements of its retarded Green's function pseudospin matrix…”

Section: Introductionmentioning

confidence: 99%

“…It is also of interest to describe the thermodynamic Green's function matrix, G( x, x ′ ; T ), which is characterized by periodicity in imaginary time (period τ = −iβ = −i/k B T ′ ) instead of retardation. It may be written in terms of its "greater" (G > ) and "lesser" (G < ) constituents as 12,15…”

Section: Introductionmentioning

confidence: 99%

Temperature Dependence of the Entropy and Magnetic Moment of Landau-Quantized Dichalcogenide Carriers in a Strong Magnetic Field

Horing

2019

Preprint

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This work addresses the temperature dependence of the statistical thermodynamic functions of the Group VI Dichalcogenides in a quantizing magnetic field. These functions include the grand partition function, the ordinary partition function, the Helmholtz Free Energy and the entropy: Their dependencies on temperature and magnetic field strength are carefully examined, particularly in the degenerate regime and the approach to zero temperature, also in the nondegenerate regime. The joint dependence on magnetic field and temperature is aso examined in the Dichalcogenide magnetic moment in both statistical regimes.

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“…Clearly, the off-diagonal elements interchange with the interchange of Dirac points (K and K ). 22,23 The Green's functions matrix in time representation can be obtained by Fourier transform of Eqs. ( 5), ( 8), (9) as…”

mentioning

confidence: 99%

Effect of pseudospin polarization on wave packet dynamics in graphene antidot lattices (GALs) in the presence of a normal magnetic field

Ayyubi

Horing

Sabeeh

2021

Journal of Applied Physics

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We have investigated the role of pseudo-spin polarization in electron wave packet dynamics in pristine graphene and in a graphene antidot lattice subject to an external magnetic field. Employing a Green's function formalism, we show that the electron dynamics can be controlled by tuning pseudospin polarization. In Landau quantized graphene, we find that an electron wave packet propagates in the direction of initial pseudospin polarization with no splitting; Zitterbewegung oscillations are found to persist. In the case of a graphene antidot lattice, the electron wave packet propagates along the axis of the antidot lattice when the initial pseudospin is parallel to this axis. We also show that the probability of finding an electron along the axis of the antidot lattice increases with the strength of the antidot potential. This suggests that a graphene antidot lattice can serve as a channel for electron transport with the possibility of tunability by means of pseudospin polarization, antidot potential and applied normal magnetic field strength.

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Landau quantized dynamics and spectra for group-VI dichalcogenides, including a model quantum wire

Cited by 15 publications

References 11 publications

Theory of Friedel oscillations in monolayer graphene and group-VI dichalcogenides in a magnetic field

Theory of Friedel oscillations in monolayer graphene and group-VI dichalcogenides in a magnetic field

Temperature Dependence of the Entropy and Magnetic Moment of Landau-Quantized Dichalcogenide Carriers in a Strong Magnetic Field

Effect of pseudospin polarization on wave packet dynamics in graphene antidot lattices (GALs) in the presence of a normal magnetic field

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