Author Correction: Phonon coherences reveal the polaronic character of excitons in two-dimensional lead halide perovskites

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Phonon coherences reveal the polaronic character of excitons in two-dimensional lead-halide perovskites

Hybrid organic-inorganic semiconductors feature complex lattice dynamics due to the ionic character of the crystal and the softness arising from non-covalent bonds between molecular moieties and the inorganic network. Here we establish that such dynamic structural complexity in a prototypical two-dimensional lead iodide perovskite gives rise to the coexistence of diverse excitonic resonances, each with a distinct degree of polaronic character. By means of high-resolution resonant impulsive stimulated Raman spectroscopy, we identify vibrational wavepacket dynamics that evolve along different configurational coordinates for distinct excitons and photocarriers. Employing density functional theory calculations, we assign the observed coherent vibrational modes to various low-frequency ($\lesssim 50$\,cm$^{-1}$) optical phonons involving motion in the lead-iodide layers. We thus conclude that different excitons induce specific lattice reorganizations, which are signatures of polaronic binding. This insight on the energetic/configurational landscape involving globally neutral primary photoexcitations may be relevant to a broader class of emerging hybrid semiconductor materials.Comment: This is a pre-print of an article published in Nature Materials. The final authenticated version is available online at https://doi.org/10.1038/s41563-018-0262-

Electron-phonon couplings inherent in polarons drive exciton dynamics in two-dimensional metal-halide perovskites

We report on the exciton formation and relaxation dynamics following photocarrier injection in a single-layer two-dimensional lead-iodide perovskite. We probe the time evolution of four distinct exciton resonances by means of time-resolved photoluminescence and transient absorption spectroscopies, and find that at 5\,K a subset of excitons form on a $\lesssim$ 1-ps timescale, and that these relax subsequently to lower-energy excitons on $\sim$ 5--10\,ps with a marked temperature dependence over $<$ 100\,K. We implement a mode projection analysis that determines the relative contribution of all observed phonons with frequency $\leq$50\,cm$^{-1}$ to inter-exciton nonadiabatic coupling, which in turn determines the rate of exciton relaxation. This analysis ranks the relative contribution of the phonons that participate in polaronic lattice distortions to the exciton inter-conversion dynamics and thus establishes their role in the nonadiabatic mixing of exciton states, and this in the exciton relaxation rate.Comment: This is a manuscript submitted to the Jean-Luc Br\'edas Festschrift in Chemistry of Material

Nonlinear Photocarrier Dynamics and the Role of Shallow Traps in Mixed-Halide Mixed-Cation Hybrid Perovskites

We examine the role of surface passivation on carrier trapping and nonlinear recombination dynamics in hybrid metal-halide perovskites by means of excitation correlation photoluminescence (ECPL) spectroscopy. We find that carrier trapping occurs on subnanosecond timescales in both control (unpassivated) and passivated samples, which is consistent within a shallow-trap model. However, the impact of passivation has a direct effect on both shallow and deep traps. Our results reveal that the effect of passivation of deep traps is responsible for the increase of the carrier lifetimes, while the passivation of shallow traps reduces the excitation density required for shallow-trap saturation. Our work demonstrates how ECPL provides details about the passivation of shallow traps beyond those available via conventional time-resolved photoluminescence techniques.</p

The molecular origin of Frenkel biexciton binding

Frenkel excitons are primary photoexcitations in molecular semiconductors and are unequivocally responsible for their optical properties. However, the spectrum of corresponding biexcitons - bound exciton pairs - has not been resolved thus far in organic materials. We correlate the energy of two-quantum exciton resonances with that of the single-quantum transition by means of nonlinear coherent spectroscopy. Using a Frenkel exciton model, we relate the biexciton binding energy to the magnitude and the sign of the exciton-exciton interaction energy and the inter-site hopping energy, which are molecular parameters that can be quantified by quantum chemistry. Unexpectedly, excitons with interchain vibronic dispersion reveal intrachain biexciton correlations, and vice-versa. The details of biexciton correlations determine exciton bimolecular annihilation, which is ubiquitous in organic semiconductors. It is crucial to quantify these interactions in order to establish a quantum-mechanical basis for their rate constants. Our work enables new opportunities for general insights into the many-body electronic structure in molecular excitonic systems such as organic semiconductor crystals, molecular aggregates, photosynthetic light-harvesting complexes, and DNA.Comment: 4 figures and Supplementary Material