Junhui Ran scite author profile

Electron beam microscopy and related characterization techniques play an important role in revealing the microstructural, morphological, physical, and chemical information of halide perovskites and their impact on associated optoelectronic devices. However, electron beam irradiation usually causes damage to these beam-sensitive materials, negatively impacting their device performance, and complicating this interpretation. In this article, the electron microscopy and spectroscopy techniques are reviewed that are crucial for the understanding of the crystallization and microstructure of halide perovskites (e.g. MAPbI 3 , CsPbBr 3 ). In addition, special attention is paid to assessing and mitigating the electron beam-induced damage caused by these techniques during measurements of both organic-inorganic hybrid and all-inorganic halide perovskites. Since the halide perovskites are fragile, a protocol involving delicate control of both electron beam dose and dose rate, coupled with careful data analysis, is shown to be the key to enable the acquisition of reliable structural and compositional information such as atomic-resolution images, chemical elemental mapping and electron diffraction patterns. Limiting the electron beam dose is shown to be the critical parameter enabling the characterization of various halide perovskite materials. Novel methods to unveil the mechanisms of device operation, including charge carrier generation, diffusion, and extraction are presented in scanning electron microscopy studies combined with electron-beam induced current and cathodoluminescence mapping. Future opportunities for electron-beam related characterizations of halide perovskites are also discussed.

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Spray-Coating Thick Films of All-Inorganic Halide Perovskites for Filterless Narrowband Photodetectors

Wang

Chen

et al. 2022

ACS Appl. Mater. Interfaces

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A significant challenge facing perovskite narrowband photodetectors is making high-quality and thick enough films. Here, we report a facile one-step spray-coating approach to deposit cesium lead halide perovskite thick films for filterless narrowband photodetectors, which exhibited a specific detectivity of 2.43 × 1010 Jones at 655 nm with an fwhm of 25 nm. We demonstrated that both substrate temperature and deposition time during the spray-coating process are key factors that govern the thickness and morphology of perovskite films. The photodetection behavior was dependent on the film thickness, and the narrowband photoresponse was recorded at a 3.9 μm thickness. We discovered that the internal electric field also plays a critical role in determining the narrowband photoresponse behavior. A distinct photoresponse behavior was observed when respectively applying a reverse bias and a forward bias, which is ascribed to the trade-off between the charge-trapping effect and charge extraction under the internal built-in electric field in different biased conditions. Through changing the halogen composition of perovskites from CsPbCl2Br to CsPbI2Br, the peak position of the narrowband spectral photoresponse was observed to shift from 460 to 660 nm. This study not only offers a controllable spray-coating approach to develop thick perovskite films but also provides an important guidance for the rational design of filterless narrowband photodetectors for practical applications in industrial control, visual imaging, and biological sensing.

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Ionic Liquid‐Tuned Crystallization for Stable and Efficient Perovskite Solar Cells

et al. 2022

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Organometal halide perovskites as the core of the next-generational photovoltaic technologies have attracted remarkable attention due to their advantages of low material cost, easy fabrication, and outstanding photovoltaic properties. [1] Significant efforts have been made to enhance the photovoltaic performance of perovskite solar cells (PSCs). [2] The power conversion efficiency (PCE) has been boosted to about 26%, [3] which is comparable to that of conventional photovoltaic technology based on crystalline silicon. Nevertheless, the device instability suffering from moisture exposure and heat attack is still a significant barrier on the road toward commercialization. [4] It is known that halide perovskites with low formation energy are intrinsically unstable so that they are easy to deteriorate under various external forces. [5] Therefore, how to stabilize the perovskite structure and films is the most important concern in the PSCs.Recently, several effective strategies, including interfacial engineering, additive engineering, dimensional manipulation, and so on, have been applied to improve device stability. [6] Caffeine (1,3,7-trimethylxanthine) was employed as an additive to increase the activation energy of perovskite films through a molecular lock between carboxyl groups and bivalent Pb, yielding PSCs with good thermal stability at 85 C. [7] Lin et al. proved that the introduction of a piperidinium salt into the perovskites could slow down degradation of the perovskite layer under continuous illumination. [8] Additionally, by depositing n-hexyl trimethyl ammonium bromide on the top of the perovskite film, a thin layer of wide-bandgap halide perovskites was formed through an in situ reaction, leading to a high efficiency of 22.7% and good stability both at 85% relative humidity and under one-sun illumination. [9] Despite these progresses, few studies have considered crystallization control of the halide perovskites, which could be a critical approach to concurrently improve both PCE and device stability. Given that the nucleation and crystallization of perovskites during both initial spin-coating and subsequent annealing process are correlated with the PbI 2 precursor solution, [10,11] it is necessary to tune crystallization of perovskite by coordinating the precursor solution to enhance chemical bonding interactions to deliver high-quality and stable perovskite films.

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Triphenylamine–Polystyrene Blends for Perovskite Solar Cells with Simultaneous Energy Loss Suppression and Stability Improvement

et al. 2020

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Energy loss induced by nonradiative recombinations plays a critical role in determining power conversion efficiencies in perovskite solar cells, whereas device stability impacts their long‐time reliability in the ambient environment. It is an important challenge to suppress energy loss and improve device stability simultaneously. Herein, an interfacial layer of triphenylamine (TPA):polystyrene (PS) blend coated on the hybrid perovskite layer to concurrently suppress energy loss and improve device stability is reported. The energy loss is suppressed from 0.49 to 0.35 eV by passivating surface defects in hybrid perovskites via Lewis acid–base interactions with the combination of electron‐donating aromatic nucleus in PS and tertiary amine in TPA, leading to perovskite solar cells with a high open‐circuit voltage of 1.18 V, a fill factor of about 80%, and a power conversion efficiency of 22.1%. Meanwhile, the device stability in the ambient environment is improved significantly by the TPA:PS blend due to its superior hydrophobicity which is suggested by its high contact angle of 91.1° as compared to 64.0° for the pristine perovskite film. Herein, an efficient interfacial engineering approach with the TPA:PS blend to suppress energy loss and improve device stability simultaneously towards realistic applications is demonstrated.

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Facile synthesis of porous organic polymers for the absorption of Pd(ii) ions and organic dyes

et al. 2016

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Junhui Ran

Electron‐Beam‐Related Studies of Halide Perovskites: Challenges and Opportunities

Spray-Coating Thick Films of All-Inorganic Halide Perovskites for Filterless Narrowband Photodetectors

Ionic Liquid‐Tuned Crystallization for Stable and Efficient Perovskite Solar Cells

Triphenylamine–Polystyrene Blends for Perovskite Solar Cells with Simultaneous Energy Loss Suppression and Stability Improvement

Facile synthesis of porous organic polymers for the absorption of Pd(ii) ions and organic dyes

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