Abstract
In recent years the physics of two-dimensional semiconductors was revived by the discovery of the class of transition metal dichalcogenides. In these systems excitons dominate the optical response in the visible range and open many perspectives for nonlinear spectroscopy. To describe the coherence and polarization dynamics of excitons after ultrafast excitation in these systems, we employ the Bloch equation model of a two-level system extended by a local field describing the exciton–exciton interaction. We calculate four-wave mixing (FWM) signals and analyze the dependence of the temporal and spectral signals as a function of the delay between the exciting pulses. Exact analytical results obtained for the case of ultrafast (δ-shaped) pulses are compared to numerical solutions obtained for finite pulse durations. If two pulses are used to generate the nonlinear signal, characteristic spectral line splittings are restricted to short delays. When considering a three-pulse excitation the line splittings, induced by the local field effect, persist for long delays. All of the found features are instructively explained within the Bloch vector picture and we show how the exciton occupation dynamics govern the different FWM signals.
Highlights
With the observation of an extraordinarily strong light emission from monolayers of transition metal dichalcogenides (TMDCs) in 2010 [1, 2], this material class came into the focus of semiconductor optics
We show that an analytic treatment in the limit of ultrafast laser pulses is possible even without restrictions to a perturbative treatment, which allows us in particular to study the dependence of the four-wave mixing (FWM) signals on the intensities of the exciting pulses
Motivated by recent nonlinear FWM measurements on TMDC monolayers we revived the Bloch equation model extended by a local field effect
Summary
Thilo Hahn1,2,∗ , Jacek Kasprzak , Paweł Machnikowski , Tilmann Kuhn and Daniel Wigger.
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