Ultrafast screening and carrier dynamics in ZnO: theory and experiment

M.A.M. Versteegh; T. Kuis; H.T.C. Stoof; J.I. Dijkhuis

doi:10.1103/PhysRevB.84.035207

Ultrafast screening and carrier dynamics in ZnO: theory and experiment

M.A.M. Versteegh, T. Kuis, H.T.C. Stoof, J.I. Dijkhuis

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Abstract

At carrier densities above the Mott density Coulomb screening destroys the exciton resonance. This, together with band-gap renormalization and band filling, severely affects the optical spectra. We have experimentally studied these effects by ultrafast pump-probe reflectivity measurements on a ZnO single crystal at various wavelengths around the exciton resonance and in a broad carrier-density range. Theoretically we determined the Mott density in ZnO to be $1.5\times10^{24}$ m$^{-3}$ at 300 K. Using the solutions of the Bethe-Salpeter ladder equation we computed the density-dependent reflectivity and absorption spectra. A carrier dynamics model has been developed, containing three-photon absorption, carrier cooling, and carrier trapping near the surface. The agreement between the theoretical reflectivity based on our model and the experimental data is excellent.

Original language	English
Pages (from-to)	035207/1-035207/19
Number of pages	19
Journal	Physical review. B, Condensed matter and materials physics
Volume	84
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevB.84.035207
Publication status	Published - 2011

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abstract = "At carrier densities above the Mott density Coulomb screening destroys the exciton resonance. This, together with band-gap renormalization and band filling, severely affects the optical spectra. We have experimentally studied these effects by ultrafast pump-probe reflectivity measurements on a ZnO single crystal at various wavelengths around the exciton resonance and in a broad carrier-density range. Theoretically we determined the Mott density in ZnO to be $1.5\times10^{24}$ m$^{-3}$ at 300 K. Using the solutions of the Bethe-Salpeter ladder equation we computed the density-dependent reflectivity and absorption spectra. A carrier dynamics model has been developed, containing three-photon absorption, carrier cooling, and carrier trapping near the surface. The agreement between the theoretical reflectivity based on our model and the experimental data is excellent.",

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AU - Stoof, H.T.C.

AU - Dijkhuis, J.I.

PY - 2011

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N2 - At carrier densities above the Mott density Coulomb screening destroys the exciton resonance. This, together with band-gap renormalization and band filling, severely affects the optical spectra. We have experimentally studied these effects by ultrafast pump-probe reflectivity measurements on a ZnO single crystal at various wavelengths around the exciton resonance and in a broad carrier-density range. Theoretically we determined the Mott density in ZnO to be $1.5\times10^{24}$ m$^{-3}$ at 300 K. Using the solutions of the Bethe-Salpeter ladder equation we computed the density-dependent reflectivity and absorption spectra. A carrier dynamics model has been developed, containing three-photon absorption, carrier cooling, and carrier trapping near the surface. The agreement between the theoretical reflectivity based on our model and the experimental data is excellent.

AB - At carrier densities above the Mott density Coulomb screening destroys the exciton resonance. This, together with band-gap renormalization and band filling, severely affects the optical spectra. We have experimentally studied these effects by ultrafast pump-probe reflectivity measurements on a ZnO single crystal at various wavelengths around the exciton resonance and in a broad carrier-density range. Theoretically we determined the Mott density in ZnO to be $1.5\times10^{24}$ m$^{-3}$ at 300 K. Using the solutions of the Bethe-Salpeter ladder equation we computed the density-dependent reflectivity and absorption spectra. A carrier dynamics model has been developed, containing three-photon absorption, carrier cooling, and carrier trapping near the surface. The agreement between the theoretical reflectivity based on our model and the experimental data is excellent.

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JO - Physical review. B, Condensed matter and materials physics

JF - Physical review. B, Condensed matter and materials physics

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Ultrafast screening and carrier dynamics in ZnO: theory and experiment

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