Chlorobenzenesulfonic Potassium Salts as the Efficient Multifunctional Passivator for the Buried Interface in Regular Perovskite Solar Cells

Carbon-based inorganic perovskite solar cells (C-PSCs) have attracted intensive attention owing to their low cost and superior thermal stability. However, the bulk defects in perovskites and interfacial energy level mismatch seriously undermine their performance. To overcome these issues, a multifunctional dualinterface engineering is proposed with a focus on low-temperature CsPbI 2 Br C-PSCs, where the potassium trifluoroacetate (KTFA) and the 4-trifluorophenyl methylammonium bromide (CF 3 PMABr) are introduced beneath and on top of the perovskite layer, respectively. It is found that TFAions locate at the SnO 2 /CsPbI 2 Br interface, whereas a small amount of K + ions diffuse into perovskite lattice to participate in nucleation and crystallization, resulting in more favored interfacial energy level alignment, improved film quality, passivated interfacial defects, released interfacial strain, as well as suppressed charge recombination and ion migration. Meanwhile, the CF 3 PMABr passivates I/Br vacancies and forms 2D perovskite capping layer to facilitate hole extraction at the CsPbI 2 Br/carbon interface. As a result, a remarkable power conversion efficiency (PCE) of 14.05% with an open-circuit voltage of 1.273 V is achieved. To the best of the authors' knowledge, it is currently the highest PCE reported for low-temperature CsPbI 2 Br C-PSCs. Furthermore, the nonencapsulated device exhibits improved moisture, thermal, and illumination stability in ambient air.

Section: Resultsmentioning

confidence: 63%

Section: Resultsmentioning

confidence: 99%

Fluorinated Interfaces for Efficient and Stable Low‐Temperature Carbon‐Based CsPbI₂Br Perovskite Solar Cells

Zhang

Zhou

et al. 2022

“…The defects at buried interface, which originate from not only the lower surface of perovskite films, but also the upper surface of SnO 2 films, are one of the main reasons for the nonradiative recombination loss of interfacial carriers. [14][15][16] The rapid crystal lization process would lead to the generation of a large number of defects in polycrystalline perovskite films, which usually dis tribute at grain boundary (GB) and interface. [17][18][19] These defects are usually deep level defects, which would bring about serious carrier nonradiative recombination and thus deteriorate device performance.…”

Section: Introductionmentioning

confidence: 99%

“…In addition, there are often a mass of oxygen vacancy defects on the surface of SnO 2 ETL, which would reduce its electron extraction and transport efficiencies, causing carrier nonradiative recombination and thereby decreasing device photovoltaic performance. [11,15,16,20] The residual strain induced by stress usually exists in perovskite films, which can be classified into compressive and tensile strain. The strain produced in perovskite films could be ascribed to many fac tors, such as coefficient of thermal expansion (CTE) difference between perovskites and charge transport materials (CTMs), lattice mismatch between perovskite film and substrate, tem perature gradient, light/bias stimulation, phase transitions, and GBs.…”

Section: Introductionmentioning

confidence: 99%

“…[26] Zhao et al incorporated CsI into SnO 2 ETL and revealed that inter facial defect passivation, perovskite crystal growth promotion, improved band alignment, and enhanced UV stability were achieved simultaneously after CsI modification for buried inter face. [14] The chlorobenzenesulfonic potassium salts (3ClBSAK) was employed by Zhong et al [16] manipulate SnO 2 /perovskite buried interface, which enabled the realization of interfacial defect passivation and suppressed nonradiative recombination along with reduced hysteresis. Although remarkable advance ments have been accomplished, the above reported interface molecules usually only can passivate the defects at buried inter face but can not release interfacial stress.…”

Section: Introductionmentioning

confidence: 99%

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Revealing Steric‐Hindrance‐Dependent Buried Interface Defect Passivation Mechanism in Efficient and Stable Perovskite Solar Cells with Mitigated Tensile Stress

Zhou

Zhuang

et al. 2022

123

Interface engineering is one feasible and effective approach to minimize the interfacial nonradiative recombination stemming from interfacial defects, interfacial residual stress, and interfacial energy level mismatch. Herein, a novel and effective steric-hindrance-dependent buried interface defect passivation and stress release strategy is reported, which is implemented by adopting a series of adamantane derivative molecules functionalized with CO (i.e., 2-adamantanone (AD), 1-adamantane carboxylic acid (ADCA), and 1-adamantaneacetic acid (ADAA)) to modify SnO 2 /perovskite interface. All modifiers play a role in passivating interfacial defects, mitigating interfacial strain, and enhancing device performance. The steric hindrance of chemical interaction between CO in these molecules and perovskites as well as SnO 2 is determined by the distance between CO and bulky adamantane ring, which gradually decreases from AD, ADCA, and ADAA. The experimental and theoretical evidences together confirmed steric-hindrance-dependent defect passivation effect and interfacial chemical interaction strength. The interfacial chemical interaction strength, defect passivation effect, stress release effect and thus device performance are negatively correlated with steric hindrance. Consequently, the ADAA-modified device achieves a seductive efficiency up to 23.18%. The unencapsulated devices with ADAA maintain 81% of its initial efficiency after aging at 60 °C for 1000 h.

Design and Synthesis of Carbazole‐Cyclopentathiophene Alternating Copolymers for Inhibiting Phase Separation of Cs_0.15FA_0.85PbI₃

Tan

Wan

Zhao

et al. 2022

To inhibit phase separation of CsxFA1−xPbI3 perovskite into optically inactive δ‐CsPbI3 and δ‐FAPbI3 under high humidity and light conditions, herein two polymers, poly[3‐methyl‐6‐(2‐methylspiro[cyclopenta[1,2‐b:5,4‐b′]dithiophene‐4,2′‐[1,3]dithiolan]‐6‐yl)‐9‐octyl‐9H‐carbazole] (TM3) and poly[3‐methyl‐6‐(2‐methylspiro[cyclopenta[1,2‐b:5,4‐b′]dithiophene‐4,2′‐[1,3]dioxolan]‐6‐yl)‐9‐octyl‐9H‐carbazole] (TM4), are designed and synthesized to dope the Cs0.15FA0.85PbI3 perovskite film for perovskite solar cells (PSCs). The results of X‐ray photoelectron spectroscopy and nuclear magnetic resonance confirm the existence of coordination and hydrogen bonds between the polymer and Cs0.15FA0.85PbI3 perovskite. Ion migration in the perovskite film is thus markedly suppressed by the TM doping, as verified by the electrical poling measurement. Benefiting from these interactions, the TM doping is able to inhibit phase separation of Cs0.15FA0.85PbI3 markedly at a relative humidity of 55–65% and under light. Furthermore, the TM doping has other positive effects such as enhancing perovskite crystallinity, improving crystal growth orientation, reducing trap density, increasing hole extraction, and suppressing charge recombination. Consequently, the TM3‐ and TM4‐doped PSCs achieve a power conversion efficiency of 21.96% and 20.01%, respectively, against 17.82% for the undoped PSC. The humidity, environmental, illumination, and thermal stabilities of unencapsulated devices are also improved significantly by the TM3‐ and TM4‐doping, respectively. By comparison, TM3 with the S substitution shows abetter effect than TM4 with the O substation on photovoltaic performance and device stability.