Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Zhou, Xin; Qi, Wenjing; Li, Jiale; Cheng, Jian; Li, Yameng; Luo, Jingshan; Ko, Min Jae; Li, Yuelong; Zhao, Ying; Zhang, Xiaodan

doi:10.1002/solr.202000308

Cited by 37 publications

(34 citation statements)

References 170 publications

(253 reference statements)

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“…Such shallow defects hence contribute to overall carrier concentrations instead of deep‐level nonradiative intraband trap states. [ 45 ] Generally, radiative band edge defects are expected to form at very high concentrations; although beneficial for light‐emitting diodes (LEDs), it is highly undesirable for solar cell applications. Defect‐tolerant studies in other systems such as transition metal dichalcogenides and other semiconductors, as shown in Figure a,b, indicate that the tendency of a material to form defect states within the bandgap is primarily influenced by the similarity of orbital characters near the conduction and valence bands of semiconductors with antibonding valence band.…”

Section: Defects In Hybrid Halide Perovskites: An Overviewmentioning

confidence: 99%

Section: Defects In Hybrid Halide Perovskites: An Overviewmentioning

confidence: 99%

“…The addition of iodine led to the formation of I 3 − , which passivated iodine vacancies. [ 45,85 ] However, the amount of excess iodine has to be optimized to achieve an optimum performance. We would like to mention here that defect passivation through excess iodine can be accomplished by adding both excess CH 3 NH 3 PbI 3 and PbI 2 in the precursor.…”

Section: Defect Passivation In Abx3mentioning

confidence: 99%

“…[43] It should be keep in mind that a combination of defects can also create dynamic defect states such as edge location (1D) and grain boundary (GB) defects (2D). [44,45] In Figure 1, we have illustrated all possible point defects in a 3D perovskite lattice (ABX 3 ), where yellow, purple, and blue dots represent the A, B, and X site, respectively, and green dots imply external impurity atoms. [43] A pioneering work in this direction has been conducted by Yin et al to study the formation energy of all intrinsic defects in the bulk of the prototype MAPbI 3 perovskite.…”

Section: Origin Of Defects and Defect Tolerancementioning

confidence: 99%

“…[44] Furthermore, DFT studies with different halide anions and monovalent cations confirmed that the defect landscape in these hybrid halide perovskites varies with composition; different perovskites have different dominant defects depending on their formation energy and balance among the possible existing defects. [45] In another notable study, DFT with generalized gradient approximation (DFT-GGA) calculations revealed the influence of Frenkel and Schottky defects on MAPbI 3 and inferred that the Schottky defects do not form trap states in the bandgap. [49] Similarly, an interesting study on the defect properties of MAPbI 3 through semilocal exchange correlation functionals, such as density functional theory-Perdew-Burke-Ernzerhof (DFT-PBE) calculations, concluded that most of the point defects in MAPbI 3 form shallow states (except I i which forms deep-level states) and do not affect the electronic properties of the perovskite.…”

Section: Theoretical Studies Of Defectsmentioning

confidence: 99%

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Defects and Their Passivation in Hybrid Halide Perovskites toward Solar Cell Applications

et al. 2020

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The rise of hybrid metal–halide perovskites as potential solar energy materials has revolutionized research on next‐generation solar cells. According to recent studies, the rationale behind such success is the rich defect physics of materials. Studies on the origin of different types of prevailing defects, their formation, and mechanism of defect passivation have hence become decisive avenues. Herein, the possible origins of defects and different defect analysis techniques in hybrid halide perovskites are discussed. While initiating the discussion with the archetypal methylammonium lead halide, perovskites beyond the conventional ABX3 structure are included. In this direction, some major advancements to date on defect formation in the bulk of hybrid halide perovskites, at the grains and grain boundaries, are summarized. Numerous effective methods to passivate the defects and the adverse effect of defects on device efficiency are further highlighted. Hence, the prospect of defect engineering in perovskite materials is pointed toward improving the power conversion efficiency and long‐term stability of perovskite solar cells (PSCs). The discussion rightfully addresses that the in‐depth exploration of defect engineering is anticipated to have a gigantic impact toward the achievement of predicted efficiency in metal–halide PSCs.

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Section: Defects In Hybrid Halide Perovskites: An Overviewmentioning

confidence: 99%

Section: Defects In Hybrid Halide Perovskites: An Overviewmentioning

confidence: 99%

Section: Defect Passivation In Abx3mentioning

confidence: 99%

Section: Origin Of Defects and Defect Tolerancementioning

confidence: 99%

Section: Theoretical Studies Of Defectsmentioning

confidence: 99%

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Defects and Their Passivation in Hybrid Halide Perovskites toward Solar Cell Applications

et al. 2020

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Efficient Inorganic Vapor‐Assisted Defects Passivation for Perovskite Solar Module

et al. 2023

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the spin-coating assisted passivation by organic molecules is easy failure due to the secondary bond such as ionic bond and hydrogen bond, [10] meanwhile, the low concentration of organic molecule passivated perovskite film is inhomogeneity, resulting in the inadequacy defects passivation. [11] Significantly, the solvents (such as isopropanol and chloroform) of passivated organic molecules also reconstruct the perovskite surface causing the uncertain type and number of defects and the weak property reproduction of PSCs. [12] While vapor-assisted defects passivation can efficiently avoid the disadvantages, thus is suitable for large-area perovskite film production instead of the solvent passivation method through the spin-coating process, which is rarely studied.Herein, we propose the inorganic vapor-assisted passivation strategy to deposit CS 2 inorganic passivation layer for high-efficiency and large-area perovskite solar module (PSM). The CS 2 molecule efficiently manages surface defects, regulates interfacial energy alignment, and enhances the properties of PSC. The uncoordinated Pb 2+ and unanchored I − on the surface of perovskite film have been passivated by the CS 2 through in situ reaction. The CS 2 can stabilize the perovskite by forming strong chemical bonds with the soft perovskite thin film, signi ficantly impeding the decomposition of perovskite components and reducing trap-state density at the grain boundaries and interfaces. Consequently, inorganic vapor-assisted defects passivation simultaneously enhances the PSC devices' efficiency and Surface trap as intrinsic defects-mediated non-radiative charge recombination is a major obstacle to achieving the reliable fabrication of high-efficiency and large-area perovskite photovoltaics. Here a CS 2 vapor-assisted passivation strategy is proposed for perovskite solar module, aiming to passivate the iodine vacancy and uncoordinated Pb 2+ caused by ion migration. Significantly, this method can avoid the disadvantages of inhomogeneity film caused by spin-coating-assisted passivation and reconstruction of perovskite surface from solvent. The CS 2 vapor passivated perovskite device presents a higher defect formation energy (0.54 eV) of iodine vacancy than the pristine (0.37 eV), while uncoordinated Pb 2+ is bonded with CS 2 . The shallow level defect passivation of iodine vacancy and uncoordinated Pb 2+ has obviously enhanced the device efficiencies (25.20% for 0.08 cm 2 and 20.66% for 40.6 cm 2 ) and the stability, exhibiting an average T 80 -lifetime of 1040 h working at the maximum power point, and maintaining over 90% of initial efficiency after 2000 h at RH = 30% and 30 °C.

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A Multifunctional Self‐Assembled Monolayer for Highly Luminescent Pure‐Blue Quasi‐2D Perovskite Light‐Emitting Diodes

Shin

Ameen

Oleiki

et al. 2022

Advanced Optical Materials

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Toward Efficient and Stable Perovskite Solar Cells: Choosing Appropriate Passivator to Specific Defects

Cited by 37 publications

References 170 publications

Defects and Their Passivation in Hybrid Halide Perovskites toward Solar Cell Applications

Defects and Their Passivation in Hybrid Halide Perovskites toward Solar Cell Applications

Efficient Inorganic Vapor‐Assisted Defects Passivation for Perovskite Solar Module

A Multifunctional Self‐Assembled Monolayer for Highly Luminescent Pure‐Blue Quasi‐2D Perovskite Light‐Emitting Diodes

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