Scaling Universality between Band Gap and Exciton Binding Energy of Two-Dimensional Semiconductors

Zeyu Jiang; Zhirong Liu; Yuanchang Li; Wenhui Duan

doi:10.1103/PhysRevLett.118.266401

Scaling Universality between Band Gap and Exciton Binding Energy of Two-Dimensional Semiconductors

Zeyu Jiang^*
, Zhirong Liu
, Yuanchang Li
, Wenhui Duan

^*Corresponding author for this work

Tsinghua University
Peking University
National Center for Nanoscience and Technology

Research output: Contribution to journal › Article › peer-review

258 Citations (Scopus)

Abstract

Using first-principles GW Bethe-Salpeter equation calculations and the k·p theory, we unambiguously show that for two-dimensional (2D) semiconductors, there exists a robust linear scaling law between the quasiparticle band gap (Eg) and the exciton binding energy (Eb), namely, Eb≈Eg/4, regardless of their lattice configuration, bonding characteristic, as well as the topological property. Such a parameter-free universality is never observed in their three-dimensional counterparts. By deriving a simple expression for the 2D polarizability merely with respect to Eg, and adopting the screened hydrogen model for Eb, the linear scaling law can be deduced analytically. This work provides an opportunity to better understand the fantastic consequence of the 2D nature for materials, and thus offers valuable guidance for their property modulation and performance control.

Original language	English
Article number	266401
Journal	Physical Review Letters
Volume	118
Issue number	26
DOIs	https://doi.org/10.1103/PhysRevLett.118.266401
Publication status	Published - 27 Jun 2017
Externally published	Yes

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title = "Scaling Universality between Band Gap and Exciton Binding Energy of Two-Dimensional Semiconductors",

abstract = "Using first-principles GW Bethe-Salpeter equation calculations and the k·p theory, we unambiguously show that for two-dimensional (2D) semiconductors, there exists a robust linear scaling law between the quasiparticle band gap (Eg) and the exciton binding energy (Eb), namely, Eb≈Eg/4, regardless of their lattice configuration, bonding characteristic, as well as the topological property. Such a parameter-free universality is never observed in their three-dimensional counterparts. By deriving a simple expression for the 2D polarizability merely with respect to Eg, and adopting the screened hydrogen model for Eb, the linear scaling law can be deduced analytically. This work provides an opportunity to better understand the fantastic consequence of the 2D nature for materials, and thus offers valuable guidance for their property modulation and performance control.",

author = "Zeyu Jiang and Zhirong Liu and Yuanchang Li and Wenhui Duan",

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AU - Jiang, Zeyu

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PY - 2017/6/27

Y1 - 2017/6/27

N2 - Using first-principles GW Bethe-Salpeter equation calculations and the k·p theory, we unambiguously show that for two-dimensional (2D) semiconductors, there exists a robust linear scaling law between the quasiparticle band gap (Eg) and the exciton binding energy (Eb), namely, Eb≈Eg/4, regardless of their lattice configuration, bonding characteristic, as well as the topological property. Such a parameter-free universality is never observed in their three-dimensional counterparts. By deriving a simple expression for the 2D polarizability merely with respect to Eg, and adopting the screened hydrogen model for Eb, the linear scaling law can be deduced analytically. This work provides an opportunity to better understand the fantastic consequence of the 2D nature for materials, and thus offers valuable guidance for their property modulation and performance control.

AB - Using first-principles GW Bethe-Salpeter equation calculations and the k·p theory, we unambiguously show that for two-dimensional (2D) semiconductors, there exists a robust linear scaling law between the quasiparticle band gap (Eg) and the exciton binding energy (Eb), namely, Eb≈Eg/4, regardless of their lattice configuration, bonding characteristic, as well as the topological property. Such a parameter-free universality is never observed in their three-dimensional counterparts. By deriving a simple expression for the 2D polarizability merely with respect to Eg, and adopting the screened hydrogen model for Eb, the linear scaling law can be deduced analytically. This work provides an opportunity to better understand the fantastic consequence of the 2D nature for materials, and thus offers valuable guidance for their property modulation and performance control.

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Scaling Universality between Band Gap and Exciton Binding Energy of Two-Dimensional Semiconductors

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