Dielectric Genome of van der Waals Heterostructures

Andersen, Kirsten; Latini, Simone; Thygesen, Kristian Sommer

doi:10.1021/acs.nanolett.5b01251

Cited by 209 publications

(286 citation statements)

References 32 publications

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“…We mention in passing that the dielectric functions of a large collection of 2D materials are available in the Computational Materials Repository [26]; see Refs. [27] and [22].…”

Section: A Macroscopic Dielectric Function For 2d Semiconductorsmentioning

confidence: 99%

“…This can be obtained using the quantum-electrostatic heterostructure (QEH) model that we introduced recently [22]. In brief, the underlying procedure in the calculation of the dielectric function can be divided in two parts.…”

Section: A the Quantum Electrostatic Heterostructure (Qeh) Modelmentioning

confidence: 99%

“…In Ref. [22] we showed, based on the comparison with full ab initio calculations, that the monopole/dipole basis is sufficient to obtain an accurate description of the dielectric and plasmonic properties of different layered heterostructures. We mention that in literature [35,36] the effect of environmental screening has been already investigated using a classical approach, proposed by Keldysh [37], based on the formation of image charges.…”

Section: A the Quantum Electrostatic Heterostructure (Qeh) Modelmentioning

confidence: 99%

“…However, in the case of 2D layers supported by semi-infinite substrates or for thicker, i.e., few-layer, 2D materials, we find it important to account for the finite thickness and include the full nonlinear q dependence of the dielectric function. In a recent paper we introduced a method for calculating the dielectric function of general layered materials (so-called van der Waals heterostructures [19][20][21]) where the dielectric functions of the individual layers are computed ab initio and subsequently coupled together electrostatically [22]. In the present work we use this method to compute the screened electron-hole interaction and solve the resulting quasi-2D Mott-Wannier model for various types of heterostructures.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Excitons in van der Waals heterostructures: The important role of dielectric screening

2015

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The existence of strongly bound excitons is one of the hallmarks of the newly discovered atomically thin semi-conductors. While it is understood that the large binding energy is mainly due to the weak dielectric screening in two dimensions (2D), a systematic investigation of the role of screening on 2D excitons is still lacking. Here we provide a critical assessment of a widely used 2D hydrogenic exciton model which assumes a dielectric function of the form (q) = 1 + 2παq, and we develop a quasi-2D model with a much broader applicability. Within the quasi-2D picture, electrons and holes are described as in-plane point charges with a finite extension in the perpendicular direction and their interaction is screened by a dielectric function with a non-linear q-dependence which is computed ab-initio. The screened interaction is used in a generalized Mott-Wannier model to calculate exciton binding energies in both isolated and supported 2D materials. For isolated 2D materials, the quasi-2D treatment yields results almost identical to those of the strict 2D model and both are in good agreement with ab-initio many-body calculations. On the other hand, for more complex structures such as supported layers or layers embedded in a van der Waals heterostructure, the size of the exciton in reciprocal space extends well beyond the linear regime of the dielectric function and a quasi-2D description has to replace the 2D one. Our methodology has the merit of providing a seamless connection between the strict 2D limit of isolated monolayer materials and the more bulk-like screening characteristics of supported 2D materials or van der Waals heterostructures.

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“…We mention in passing that the dielectric functions of a large collection of 2D materials are available in the Computational Materials Repository [26]; see Refs. [27] and [22].…”

Section: A Macroscopic Dielectric Function For 2d Semiconductorsmentioning

confidence: 99%

Section: A the Quantum Electrostatic Heterostructure (Qeh) Modelmentioning

confidence: 99%

Section: A the Quantum Electrostatic Heterostructure (Qeh) Modelmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Excitons in van der Waals heterostructures: The important role of dielectric screening

2015

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“…In the long-wavelength limit, ε 1 (q) is fully determined by the dielectric background: ε 1 (q → 0) = ε sub . In the opposite limit (q 1Å −1 ), screening in the undoped case is solely due to the microscopic inter-band polarizability of the MoS 2 layer itself, ε 1 (q) ≈ 9.3 ≡ ε ∞ , but unaffected by the dielectric environment 33,34 .…”

Section: Electronic Structure and Coulomb Interactionsmentioning

confidence: 99%

Interplay of screening and superconductivity in low-dimensional materials

et al. 2016

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A quantitative description of Coulomb interactions is developed for two-dimensional superconducting materials, enabling us to compare intrinsic with external screening effects, such as those due to substrates. Using the example of a doped monolayer of MoS 2 embedded in a tunable dielectric environment, we demonstrate that the influence of external screening is limited to a length scale, bounded from below by the effective thickness of the quasi two-dimensional material and from above by its intrinsic screening length. As a consequence, it is found that unconventional Coulomb driven superconductivity cannot be induced in MoS 2 by tuning the substrate properties alone. Our calculations of the retarded Morel-Anderson Coulomb potential µ * reveal that the Coulomb interactions, renormalized by the reduced layer thickness and the substrate properties, can shift the onset of the electron-phonon driven superconducting phase in monolayer MoS 2 but do not significantly affect the critical temperature at optimal doping.

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A Multibeam Interference Model for Analyzing Complex Near‐Field Images of Polaritons in 2D van der Waals Microstructures

Liao

Guo

et al. 2019

Adv Funct Materials

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Van der Waals (vdW) materials are among the most promising candidates for photonic integrated circuits because they support a full set of polaritons that can manipulate light at deep subdiffraction nanoscale. It is possible to directly probe the propagating polaritons in vdW materials in real space via scattering-type scanning near-field optical microscopy, such that the wave vector and lifetime of the polaritons can be extracted from as-measured interference fringes by Fourier analysis. However, this method is unsuitable for clutter interference patterns in samples exhibiting inadequate fringes due to small size (less than 10 µm) or complex edges that are often encountered in nanophotonic devices and new material characterization. Here, a multibeam interference model is developed to analyze complex images by disentangling them into periodic patterns and residue. By employing phase stationary approximation, polariton wave vector can be derived from offset ratio of the center point, and the ratio of polariton reflection and scattering rates at the edge is obtained from the ratio of the periodic and aperiodic patterns. This method can be widely used in the optical characterization of new vdW materials that are difficult to synthesize into large crystals, as well as nanophotonic integrated devices with unique boundaries.

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Dielectric Genome of van der Waals Heterostructures

Cited by 209 publications

References 32 publications

Excitons in van der Waals heterostructures: The important role of dielectric screening

Excitons in van der Waals heterostructures: The important role of dielectric screening

Interplay of screening and superconductivity in low-dimensional materials

A Multibeam Interference Model for Analyzing Complex Near‐Field Images of Polaritons in 2D van der Waals Microstructures

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