Advances in Metal Halide Perovskite Film Preparation: The Role of Anti‐Solvent Treatment

Sun, Jianguo; Li, Fangchao; Yuan, Jianyu; Ma, Wanli

doi:10.1002/smtd.202100046

Cited by 54 publications

(55 citation statements)

References 145 publications

(168 reference statements)

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confidence: 99%

Indigo: A Natural Molecular Passivator for Efficient Perovskite Solar Cells

Guo

Sun

et al. 2022

Advanced Energy Materials

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Benefiting from these unique properties, the power conversion efficiency (PCE) of perovskite solar cells (PSCs) has rapidly increased from initial ≈3% to now 25.5%, [7][8][9] situating it at the forefront of the third-generation solar cells. [10,11] Unfortunately, these ionic hybrid perovskite materials are extremely sensitive to light, [12,13] heat, [14] and moisture, [15] resulting in unstable crystal structures. During the past decade, numerous passivating methods have been developed to enhance both efficiency and long-term stability of hybrid PSCs. [16][17][18] In these polycrystalline perovskite films, defects formed at either surface or grain boundaries have been widely reported to significantly restrict carriers transport and crystal stability, which further deteriorates the device performance. [19,20] Indeed, a large number of defects are generated during the film crystallization process due to the low formation energy and soft lattice character of the perovskite crystals. [21,22] Besides, the ionic nature of hybrid halide perovskite leads to unfavorable carrier recombination and ion migration in the perovskite films, resulting in unsatisfactory efficiency or stability of the devices. [23,24] In particular, the crystallization process is accompanied by the ubiquitous formation of imperfections at grain boundaries and surfaces, metallic lead clusters, and intrinsic point defects. [24][25][26] Among them, intrinsic site Organic-inorganic hybrid lead halide perovskite solar cells have made unprecedented progress in improving photovoltaic efficiency during the past decade, while still facing critical stability challenges. Herein, the natural organic dye Indigo is explored for the first time to be an efficient molecular passivator that assists in the preparation of high-quality hybrid perovskite film with reduced defects and enhanced stability. The Indigo molecule with both carbonyl and amino groups can provide bifunctional chemical passivation for defects. In-depth theoretical and experimental studies show that the Indigo molecules firmly binds to the perovskite surfaces, enhancing the crystallization of perovskite films with improved morphology. Consequently, the Indigo-passivated perovskite film exhibits increased grain size with better uniformity, reduced grain boundaries, lowered defect density, and retarded ion migration, boosting the device efficiency up to 23.22%, and ≈21% for large-area device (1 cm 2 ). Furthermore, the Indigo passivation can enhance device stability in terms of both humidity and thermal stress. These results provide not only new insights into the multipassivation role of natural organic dyes but also a simple and low-cost strategy to prepare high-quality hybrid perovskite films for optoelectronic applications based on Indigo derivatives.

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Indigo: A Natural Molecular Passivator for Efficient Perovskite Solar Cells

Guo

Sun

et al. 2022

Advanced Energy Materials

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“…TiO 2 nanomaterial exhibits superior textural properties such as high surface area (a large number of contact sides to promote the adsorption of dye molecules), and optimum electron transfer. It has been reported elsewhere that commercial TiO 2 exhibits a band gap of 3.0–3.2 eV 9 [ 89 ]…”

Section: Third Generationmentioning

confidence: 99%

Solar Energy Materials-Evolution and Niche Applications: A Literature Review

2022

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The demand for energy has been a global concern over the years due to the ever increasing population which still generate electricity from non-renewable energy sources. Presently, energy produced worldwide is mostly from fossil fuels, which are non-renewable sources and release harmful by-products that are greenhouses gases. The sun is considered a source of clean, renewable energy, and the most abundant. With silicon being the element most used for the direct conversion of solar energy into electrical energy, solar cells are the technology corresponding to the solution of the problem of energy on our planet. Solar cell fabrication has undergone extensive study over the past several decades and improvement from one generation to another. The first solar cells were studied and grown on silicon wafers, in particular single crystals that formed silicon-based solar cells. With the further development in thin films, dye-sensitized solar cells and organic solar cells have significantly enhanced the efficiency of the cell. The manufacturing cost and efficiency hindered further development of the cell, although consumers still have confidence in the crystalline silicon material, which enjoys a fair share in the market for photovoltaics. This present review work provides niche and prominent features including the benefits and prospects of the first (mono-poly-crystalline silicon), second (amorphous silicon and thin films), and third generation (quantum dots, dye synthesized, polymer, and perovskite) of materials evolution in photovoltaics.

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“…Then, a compact SnO 2 layer was deposited by a solution process using a spin coater, and the spin-coated film was annealed at 160 • C for 30 min. The perovskite precursor solution was spin-coated onto the SnO 2 layer while anhydrous diethyl ether, to treat the layer during the anti-solvent process [34], was slowly dripped on top of the substrate. Subsequently, the film was annealed at 100 • C for 10 min to obtain a dense CH 3 NH 3 PbI 3 film.…”

Section: Fabrication Of Monolithic Perovskite-carrier Selective Contact Silicon Tandem Solar Cellmentioning

confidence: 99%

Monolithic Perovskite-Carrier Selective Contact Silicon Tandem Solar Cells Using Molybdenum Oxide as a Hole Selective Layer

et al. 2021

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Monolithic perovskite–silicon tandem solar cells with MoOx hole selective contact silicon bottom solar cells show a power conversion efficiency of 8%. A thin 15 nm-thick MoOx contact to n-type Si was used instead of a standard p+ emitter to collect holes and the SiOx/n+ poly-Si structure was deposited on the other side of the device for direct tunneling of electrons and this silicon bottom cell structure shows ~15% of power conversion efficiency. With this bottom carrier selective silicon cell, tin oxide, and subsequent perovskite structure were deposited to fabricate monolithic tandem solar cells. Monolithic tandem structure without ITO interlayer was also compared to confirm the role of MoOx in tandem cells and this tandem structure shows the power conversion efficiency of 3.3%. This research has confirmed that the MoOx layer simultaneously acts as a passivation layer and a hole collecting layer in this tandem structure.

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Advances in Metal Halide Perovskite Film Preparation: The Role of Anti‐Solvent Treatment

Cited by 54 publications

References 145 publications

Indigo: A Natural Molecular Passivator for Efficient Perovskite Solar Cells

Indigo: A Natural Molecular Passivator for Efficient Perovskite Solar Cells

Solar Energy Materials-Evolution and Niche Applications: A Literature Review

Monolithic Perovskite-Carrier Selective Contact Silicon Tandem Solar Cells Using Molybdenum Oxide as a Hole Selective Layer

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