Probing femtosecond lattice displacement upon photo-carrier generation in lead halide perovskite

Abstract: Electronic properties and lattice vibrations are expected to be strongly correlated in metal-halide perovskites, due to the soft fluctuating nature of their crystal lattice. Thus, unveiling electron–phonon coupling dynamics upon ultrafast photoexcitation is necessary for understanding the optoelectronic behavior of the semiconductor. Here, we use impulsive vibrational spectroscopy to reveal vibrational modes of methylammonium lead-bromide perovskite under electronically resonant and non-resonant conditions. We… Show more

“…82 In MAPbX 3 , lattice displacement after photoinduced carrier generation was probed through impulsive vibrational spectroscopy, providing further experimental evidence of the polaronic nature of the photoexcitation. 83,84 In low-dimensional systems, the coulombic and dielectric confinement sustain tightly bound excitons which interact with the highly polar lead halide framework. Recently, strong photoinduced lattice deformations have been identified in several 2D perovskites, where excitonic polarons must be considered to account for their characteristic luminescence and absorption line-shapes.…”

White light emission in low-dimensional perovskites

“…82 In MAPbX 3 , lattice displacement after photoinduced carrier generation was probed through impulsive vibrational spectroscopy, providing further experimental evidence of the polaronic nature of the photoexcitation. 83,84 In low-dimensional systems, the coulombic and dielectric confinement sustain tightly bound excitons which interact with the highly polar lead halide framework. Recently, strong photoinduced lattice deformations have been identified in several 2D perovskites, where excitonic polarons must be considered to account for their characteristic luminescence and absorption line-shapes.…”

White light emission in low-dimensional perovskites

“…Upon disclosure of the first reports on efficient solid state perovskite solar cells, one of the main surprises was the high open circuit voltage of such devices despite the absorber materials being solution processed. The reported long carrier lifetimes and diffusion lengths have directed a considerable amount of research toward investigating the nature of the carriers, and the role of electronic structure in their transport and dynamics. To complete the picture, researchers require an accurate understanding of the role played by defects in the photophysics of these materials, which by extension requires an understanding of the chemical nature and activity of those defects.…”

Defect Activity in Lead Halide Perovskites

“…Furthermore, Raman spectroscopy benefits from resonance enhancements of specific chromophore signatures and thereby provides a route to comprehensively investigate vibrational energy flow during reactive transformations by selectively probing specific environments [25]. In particular, time-domain impulsive stimulated Raman scattering (ISRS) [26][27][28][29][30][31][32][33][34][35][36] offers several advantages over its frequency-domain analogues for the detection of vibronic features, especially for low-frequency modes, by efficiently removing elastic scattering contributions and background noise [37][38][39][40]. Its multidimensional extension, 2D-ISRS, has been theoretically proposed initially [41] and realized in both nonresonant [42,43] and resonant [44,45] implementations to study ground-state intramolecular vibrational anharmonicities, nonlinear corrections to the molecular polarizability, product-reactant correlations, and solvation dynamics, up to the recent realization of single-pulse 2D spectroscopy by means of appropriately shaped light pulses [46], with possible applications theoretically suggested for the x-ray domain [47].…”

Two-Dimensional Impulsively Stimulated Resonant Raman Spectroscopy of Molecular Excited States