Science des matériaux

Exciton dynamics and non-linearities in hybrid organic perovskites

Publié le - Physics and Nanoelectronics Workshop : « 2D materials : from physics to engineering »

Auteurs : Katia Abdel-Baki, Fabien Boitier, Hiba Diab, Khaoula Jemli, Ferdinand Lédée, Damien Garrot, Emmanuelle Deleporte, Jean‐sébastien Lauret

Due to their high potentiality for photovoltaic applications or coherent light sources, a great interest in hybrid organic perovskites (HOP) has emerged since 2012. Some of these HOPs are arranged in two dimensions, presenting an electronic structure of semiconducting multi-quantum wells. In these 2D HOPs, a huge exciton binding energy of several 100 meV, that can be tailored through chemical engineering, is found. The engineering of excitonic effects in 2D-HOPs is of great importance in order to use these materials as amplification medium for coherent light sources. We report here ultrafast time-resolved measurements and pump-probe spectroscopy performed on (C6H5C2H4NH3)2PbI4 thin layers at room temperature. The exciton dynamics is fitted with a bi-exponential decay with a free exciton life-time of ∼100 ps. The presence of a long tail in the pump/probe signal is attributed to trapped excitons on dark states. An ultrafast intraband relaxation (τintra ≤ 150 fs) is reported. The transient modification of the excitonic line is analyzed through the moment analysis and described in terms of reduction of the oscillator strength and linewidth broadening. We find that 2D-HOPs share common behaviours with standard semiconductors quantum wells, despite their huge exciton binding energy that is closer to the one reported for organic semiconductors. Nevertheless, the quantitative differences in the amplitudes of the transient phenomena highlight the need to take into account screening effects in the description of excitonic nonlinearities of 2D-HOPs.