Quasiparticle energies, excitons, and optical spectra of few-layer black phosphorus

Vy Tran; Ruixiang Fei; Li Yang

doi:10.1088/2053-1583/2/4/044014

Quasiparticle energies, excitons, and optical spectra of few-layer black phosphorus

Vy Tran, Ruixiang Fei, Li Yang

Washington University St. Louis

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

83 Citations (Scopus)

Abstract

Wereport first-principles GW-Bethe-Salpeter-equation (BSE) studies of excited-state properties of few-layer black phosphorus (BP) (phosphorene). With improved GW computational methods, we obtained converged quasiparticle band gaps and optical absorption spectra by the single-shot (G₀W₀) procedure. Moreover, we reveal fine structures of anisotropic excitons, including the series of one dimensional like wave functions, spin singlet-triplet splitting, and electron-hole binding energy spectra by solving BSE. An effective-mass model is employed to describe these electron-hole pairs, shedding light on estimating the exciton binding energy of anisotropic two-dimensional semiconductors without expensive ab initio simulations. Finally, the anisotropic optical response of BP is explained by using optical selection rules based on the projected single-particle density of states at band edges.

Original language	English
Article number	044014
Journal	2D Materials
Volume	2
Issue number	4
DOIs	https://doi.org/10.1088/2053-1583/2/4/044014
Publication status	Published - 23 Nov 2015
Externally published	Yes

Keywords

Band gap
Black phosphorus
Exciton
Exciton spectra
Singlet-triplet splitting

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10.1088/2053-1583/2/4/044014

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title = "Quasiparticle energies, excitons, and optical spectra of few-layer black phosphorus",

abstract = "Wereport first-principles GW-Bethe-Salpeter-equation (BSE) studies of excited-state properties of few-layer black phosphorus (BP) (phosphorene). With improved GW computational methods, we obtained converged quasiparticle band gaps and optical absorption spectra by the single-shot (G0W0) procedure. Moreover, we reveal fine structures of anisotropic excitons, including the series of one dimensional like wave functions, spin singlet-triplet splitting, and electron-hole binding energy spectra by solving BSE. An effective-mass model is employed to describe these electron-hole pairs, shedding light on estimating the exciton binding energy of anisotropic two-dimensional semiconductors without expensive ab initio simulations. Finally, the anisotropic optical response of BP is explained by using optical selection rules based on the projected single-particle density of states at band edges.",

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AU - Tran, Vy

AU - Fei, Ruixiang

AU - Yang, Li

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N2 - Wereport first-principles GW-Bethe-Salpeter-equation (BSE) studies of excited-state properties of few-layer black phosphorus (BP) (phosphorene). With improved GW computational methods, we obtained converged quasiparticle band gaps and optical absorption spectra by the single-shot (G0W0) procedure. Moreover, we reveal fine structures of anisotropic excitons, including the series of one dimensional like wave functions, spin singlet-triplet splitting, and electron-hole binding energy spectra by solving BSE. An effective-mass model is employed to describe these electron-hole pairs, shedding light on estimating the exciton binding energy of anisotropic two-dimensional semiconductors without expensive ab initio simulations. Finally, the anisotropic optical response of BP is explained by using optical selection rules based on the projected single-particle density of states at band edges.

AB - Wereport first-principles GW-Bethe-Salpeter-equation (BSE) studies of excited-state properties of few-layer black phosphorus (BP) (phosphorene). With improved GW computational methods, we obtained converged quasiparticle band gaps and optical absorption spectra by the single-shot (G0W0) procedure. Moreover, we reveal fine structures of anisotropic excitons, including the series of one dimensional like wave functions, spin singlet-triplet splitting, and electron-hole binding energy spectra by solving BSE. An effective-mass model is employed to describe these electron-hole pairs, shedding light on estimating the exciton binding energy of anisotropic two-dimensional semiconductors without expensive ab initio simulations. Finally, the anisotropic optical response of BP is explained by using optical selection rules based on the projected single-particle density of states at band edges.

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KW - Exciton

KW - Exciton spectra

KW - Singlet-triplet splitting

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Quasiparticle energies, excitons, and optical spectra of few-layer black phosphorus

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Keywords

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