Optical properties of a semi-Dirac material

Ćarbotte, J. P.; Bryenton, Kyle R.; Nicol, E. J.

doi:10.1103/physrevb.99.115406

Cited by 50 publications

(38 citation statements)

References 64 publications

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“…Notice that apart from ϕ ter yy and ϕ tra yy , the anisotropy in the energy dispersion introduces an additional scaling factor v y /v x to σ yy , in agreement with calculations using the Landauer formalism [38] or in a semi-Dirac material [47].…”

Section: A Conductivity In the Direction Parallel To The Tiltsupporting

confidence: 81%

Kubo conductivity for anisotropic tilted Dirac semimetals and its application to 8-Pmmnborophene: Role of frequency, temperature, and scattering limits

Herrera

Naumis

2019

Phys. Rev. B

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The electronic and optical conductivities for anisotropic tilted Dirac semimetals are calculated using the Kubo formula. As in graphene, it is shown that the minimal conductivity is sensitive to the order in which the temperature, frequency and scattering limits are taken. Both intraband and interband scattering are found to be direction dependent. In the high frequency and low temperature limit, the conductivities do not depend on frequency and are weighted by the anisotropy in such a way that the geometrical mean √ σxxσyy of the conductivity is the same as in graphene. This results from the fact that in the zero temperature limit, interband transitions are not affected by the tilt in the dispersion, a result that is physically interpreted as a global tilting of the allowed transitions. Such result is verified by an independent and direct calculation of the absorption coefficient using the Fermi golden rule. However, as temperature is raised, an interesting minimum is observed in the interband scattering, interpreted here as a result of the interplay between the tilt and the chemical potential increasing with temperature.

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Section: A Conductivity In the Direction Parallel To The Tiltsupporting

confidence: 81%

Kubo conductivity for anisotropic tilted Dirac semimetals and its application to 8-Pmmnborophene: Role of frequency, temperature, and scattering limits

Herrera

Naumis

2019

Phys. Rev. B

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“…It is easy to find that, unlike the result obtained base on anisotropic model as shown above, the DOS obtained in low-density approximation is independent of energy ω in some certain region: for upper branch, nonzero constant DOS requires ω + µ i > D, while for lower branch, nonzero constant DOS requires ω + µ i < D. This is different to both the intrinsic Dirac systems (or some other graphene-related complex junction structures [94,100]) which has a DOS linear with energy in low-energy regime [97,92], and the semi-Dirac systems whose DOS is proportional to √ ω as we stated above. Such special phenomenon in DOS (constant, but not follow the power law behavior) is similar to the normal 2D electron gas, and can also be found in the bilayer graphene [98,113] or other bilayer Dirac-like systems under magnetic field [99,114] (if we ignore the largest peak in zero energy which is contributed by a doubly degenerated level). That also implies in low carrier density approximation the semi-Dirac system can be approximately treated as 2D electron gas although with different effective masses in different directions.…”

Section: Isotropic Treatment: Low Carrier-density Approximationmentioning

confidence: 59%

“…We investigate the electronic properties of semi-Dirac system as well as the related polaronic dynamics as a semi-Dirac quasiparticle (impurity) immersed into a medium (two-dimensional (2D) electron gas). Semi-Dirac 2D material, which exhibits a relativistic dispersion in one direction and nonrelativistic in another, has surge a great research interest [125,114]. Besides, due to the existence of nonadiabatic feature in the nonrelativistic direction, the polaronic effect would be foud as the minority semi-Dirac quasiparticles interact with the quadratic majority particles (particle-hole excitations) in 2D electron gas.…”

Section: Introductionmentioning

confidence: 99%

Electronic properties and polaronic dynamics of semi-Dirac system within Ladder approximation

2020

Phys. Scr.

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We investigate the electronic properties of the semi-Dirac system and its polaronic dynamics when coupled with a fermi bath with quadratic dispersion. The electronic anisotropic transport properties and the semiclassical dynamics of the semi-Dirac system are studied, including the density-of-states, conductivity, transport relaxation rate, specific heat, electrical current denity, and free energy. The attractive polaron formed as the semi-Dirac impurity dressed with the particle-hole excitations in a two-dimensional system are studied both analytically and numerically. The pair propagator, self-energy, spectral function are being detailly calculated and discussed. The method of medium T -matrix approximation (non-self-consistent), which equivalent to the partially dressed interaction vertex by summing over all ladder diagrams, is applied, and compared with some other methods (for many-body problem), like the leading-order 1/N expansion (GW approximation), Hartree-Fock theory, and the Nozieres-Schmitt-Rink theory. Since we foucs on the weak-coupling region, the mean-field approximation is also applicable. The polaron properties is related to the anisotropic effective masses of the semi-Dirac system. That's in contrast to the polarons formed in the surface of normal Dirac systems which has an isotropic dispersion, since the anisotropic dispersion of the semi-Dirac systems results in anisotropic effective mass and anisotropic charge carrier transport. Besides, the symmetry between electron and hole is also broken since the effective masses of the electron and hole are different, which are affected by the polaronic effect when the semi-Dirac material is deposited on a polar substrate, like hBN. The self-localization, short-range potential, and experimental methods as well as the possible formation of the bose polaron on the surface of semi-Dirac system are also discussed in the end. Our results are useful also for the investigation of two/three-dimensional bosonic polaron as well as the polarons in other solid state systems, like the magnetic matter or the topological systems. *

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“…The optical properties contain fundamental features of materials, including optical conductivity, dielectric function, refractive index, reflectivity, and transmission that can be measured by experiments [1][2][3][4][5][6][7][8][9], and have been widely studied for a variety of compounds, such as solids [10][11][12][13], nanoparticles [14,15], 2D materials [16][17][18][19][20], superconductors [21][22][23][24], and biological tissues [25]. The optical conductivity and dielectric function of materials are two important measurable quantities for understanding natural phenomena, such as current density caused by an alternative electric field, optical transitions, and energy dissipation [26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Unfolding optical transition weights of impurity materials for first-principles LCAO electronic structure calculations

Lee

Fukuda

et al. 2020

Phys. Rev. B

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A method to analyze optical transitions is developed by combining the Kubo-Greenwood formula with the unfolding method to construct an unfolded electronic band structure with optical transition weights, which allows us to investigate how optical transitions are perturbed by imperfections such as impurity, vacancy, and structural distortions. Based on the Kubo-Greenwood formula, we first calculate frequency-dependent optical conductivity based on the first-principles electronic structure calculations using the linear combinations of atomic orbitals. Benefiting from the atomic orbital basis sets, the frequency-dependent optical conductivity can be traced back to their individual components before summations over all of k points and bands. As a result, optical transition weights of the material can be put on the unfolded electronic band structure to show contributions at different k points and bands. This method is especially useful to study the effects of broken symmetry in the optical transitions due to presence of impurities in the materials. As a demonstration, decomposed optical transition weights of a monolayer Si-doped graphene are shown in the electronic band structure.

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Optical properties of a semi-Dirac material

Cited by 50 publications

References 64 publications

Kubo conductivity for anisotropic tilted Dirac semimetals and its application to 8-Pmmnborophene: Role of frequency, temperature, and scattering limits

Kubo conductivity for anisotropic tilted Dirac semimetals and its application to 8-Pmmnborophene: Role of frequency, temperature, and scattering limits

Electronic properties and polaronic dynamics of semi-Dirac system within Ladder approximation

Unfolding optical transition weights of impurity materials for first-principles LCAO electronic structure calculations

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