Jean‐Baptiste Puel scite author profile

Interface engineering through passivating agents, in the form of organic molecules, is a powerful strategy to enhance the performance of perovskite solar cells. Despite its pivotal function in the development of a rational device optimization, the actual role played by the incorporation of interfacial modifications and the interface physics therein remains poorly understood. Here, we investigate the interface and device physics, quantifying charge recombination and charge losses in state-of-the-art inverted solar cells with power conversion efficiency beyond 23% - among the highest reported so far - by using multidimensional photoluminescence imaging. By doing that we extract physical parameters such as quasi-Fermi level splitting (QFLS) and Urbach energy enabling us to assess that the main passivation mechanism affects the perovskite/PCBM ([6,6]-phenyl-C61-butyric acid methyl ester) interface rather than surface defects. In this work, by linking optical, electrical measurements and modelling we highlight the benefits of organic passivation, made in this case by phenylethylammonium (PEAI) based cations, in maximising all the photovoltaic figures of merit.

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Spatial Inhomogeneity Analysis of Cesium-Rich Wrinkles in Triple-Cation Perovskite

Bercegol

Ramos

Rebai

et al. 2018

J. Phys. Chem. C

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Chemical composition engineering in metal halide perovskite leads to enhanced stability and better transport properties, opening the gate to their integration in competitive photovoltaic tandem devices or LEDs. However, triple-cation perovskites show morphological, chemical, optical, and optoelectronic heterogeneities. In this study, we focus on micrometric spatial inhomogeneities where we observe wrinkle formation in the fabrication process linked to the cesium addition. Electron-dispersive spectroscopy and photoluminescence (PL) hyperspectral imaging designate these morphological features as Cs-rich and N-poor, which underlines the role of long-range chemical migration in the perovskite formation. We also study charge-carrier diffusion and recombination using time-resolved PL imaging under wide-field illumination, which we correlate with 3D drift diffusion modeling. We underline the impact of wrinkles on local optoelectronic properties such as the bandgap opening due to Cs enrichment and the longer charge carrier lifetime due to lower trap density.

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In-Depth Chemical and Optoelectronic Analysis of Triple-Cation Perovskite Thin Films by Combining XPS Profiling and PL Imaging

Cacovich

Dally

Vidon

et al. 2022

ACS Appl. Mater. Interfaces

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The investigation of chemical and optoelectronic properties of halide perovskite layers and associated interfaces is crucial to harness the full potential of perovskite solar cells. Depth-profiling photoemission spectroscopy is a primary tool to study the chemical properties of halide perovskite layers at different scales from the surface to the bulk. The technique employs ionic argon beam thinning that provides accurate layer thicknesses. However, there is an urgent need to corroborate the reliability of data on chemical properties of halide perovskite thin films to better assess their stability. The present study addresses the question of the Ar+ sputtering thinning on the surface chemical composition and the optoelectronic properties of the triple-cation mixed-halide perovskite by combining X-ray photoemission spectroscopy (XPS) and photoluminescence (PL) spectroscopy. First, XPS profiling is performed by Ar+ beam sputtering on a half-cell: glass/FTO/c-TiO2/perovskite. The resulting profiles show a very homogeneous and reproducible element distribution until near the buried interface; therefore, the layer is considered as quasihomogeneous all over its thickness, and the sputtering process is stable. Second, we evaluated a set of thinned perovskite layers representative of selected steps along the profile by means of PL imaging optical measurements in both steady-state and transient regimes to assess possible perturbation of the optical properties from the surface to bulk. Obtained PL spectra inside the resulting craters show no peak shift nor phase segregation. Accordingly, the transient PL measurements do not reveal any changes of the surface recombination rate in the sputtered areas. This demonstrates that there is no cumulative effect of sputtering nor drastic chemical and optoelectronic modifications, validating the determination of the in-depth composition of the perovskite layer. Combining XPS profiling with PL characterization can be a precise tool to be applied for an extensive study of the multiple layers and mixed organic/inorganic interfaces of photovoltaic devices.

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