Impact of photoinduced phase segregation in mixed-halide perovskite absorbers on their material and device stability

APL Energy Pub Date : 2024-03-01 DOI:10.1063/5.0190465
Shivam Singh, Ellen Moons
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Abstract

Mixed-halide perovskites enable bandgap engineering for tandem solar cell and light-emitting diode applications. However, photoinduced halide phase segregation introduces a compositional instability, that is, formation of I-rich and Br-rich phases, which compromises photovoltaic efficiency and stability. While optical and structural studies of the photoinduced phase segregation in mixed-halide perovskites have been reported, its impact on the material stability is missing. Here, a detailed compositional analysis of mixed-halide perovskite films using x-ray and ultraviolet photoelectron spectroscopy (UPS) was carried out to determine how their stability in various environments depends on the halide ratio. A series of perovskite thin films were fabricated with the composition CH3NH3Pb(IxBr1−x)3, where x = 0.00, 0.25, 0.50, 0.75, and 1.00, and analyzed under different conditions, such as exposure to light in ambient and in nitrogen atmosphere, as well as storage in the dark. From the spectroscopy results, complemented with structural and optical properties, it was found that the deletion of halide ions from the surface is facilitated in mixed-halide perovskites in comparison with pure halide perovskites. A higher stability was found for the mixed-halide perovskite containing less than 25% Br, and it decreases with increasing Br content. This study also established the effect of the Br/I ratio on the energy landscape of the materials. The UPS spectra reveal that photoinduced degradation results in a mismatch of the energy levels at the perovskite/transport layer interface, which may limit the collection of charge carriers. These findings correlate well with the photovoltaic device stability under similar degradation conditions.
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混合卤化物过氧化物吸收体中的光诱导相分离对其材料和设备稳定性的影响
混合卤化物过氧化物可用于串联太阳能电池和发光二极管的带隙工程。然而,光诱导卤化物相分离会带来成分不稳定性,即形成富含 I 和富含 Br 的相,从而影响光伏效率和稳定性。虽然对混合卤化物包晶石中光诱导相偏析的光学和结构研究已有报道,但其对材料稳定性的影响还未见报道。在此,我们利用 X 射线和紫外线光电子能谱(UPS)对混合卤化物透镜薄膜进行了详细的成分分析,以确定它们在各种环境中的稳定性如何取决于卤化物的比例。研究人员制备了一系列成分为 CH3NH3Pb(IxBr1-x)3 (其中 x = 0.00、0.25、0.50、0.75 和 1.00)的包晶薄膜,并在不同条件下(如在环境和氮气中暴露于光以及在黑暗中储存)对其进行了分析。光谱结果以及结构和光学特性表明,与纯卤化物包晶相比,混合卤化物包晶有利于从表面去除卤离子。研究发现,卤化物含量低于 25% 的混合卤化物包光体具有更高的稳定性,而且这种稳定性随着卤化物含量的增加而降低。这项研究还确定了 Br/I 比对材料能谱的影响。UPS 光谱显示,光诱导降解导致了包晶/传输层界面能级的不匹配,这可能会限制电荷载流子的收集。这些发现与类似降解条件下的光伏设备稳定性密切相关。
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