Suppressing Nonradiative Recombination in Lead–Tin Perovskite Solar Cells through Bulk and Surface Passivation to Reduce Open Circuit Voltage Losses

Zhang, Kaicheng; Späth, Andreas; Almora, Osbel; Corre, Vincent M. Le; Wortmann, Jonas; Zhang, Jiyun; Xie, Zhiqiang; Barabash, Anastasia; Hammer, Maria S.; Heumüller, Thomas; Min, Jie; Fink, R.; Lüer, Larry; Li, Ning; Brabec, Christoph J.

doi:10.1021/acsenergylett.2c01605

Cited by 38 publications

(39 citation statements)

References 47 publications

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“…94 Therefore, effective defect suppression can be achieved by the surface passivation strategy through appropriate treating methods. 143 As mentioned before, the use of a 2D surface passivation layer can efficiently reduce the defect concentrations at GBs and on the film surface, which prohibited the corrosion of oxygen and water into the perovskite lattice to improve the cell performance. For instance, Hu et al have added a SnF 2 •3FACl additive into the all-inorganic CsPb 0.6 Sn 0.4 I 3 precursor solution to prohibit the Sn 2+ oxidation and functionalize GBs.…”

Section: Crystallization Controlmentioning

confidence: 95%

“…Therefore, several functional additives for the Sn 2+ cation stabilization, such as Sn metal powder, SnF 2 , and organic reducing agents, to the perovskite precursor solution effectively inhibited the Sn 2+ cation oxidation, reducing the defect density of Pb–Sn NBG PSCs. , For the Pb–Sn perovskites, it has been reported that the Sn 2+ oxidation mainly occurs at the GBs and on the surface of the perovskite film . Therefore, effective defect suppression can be achieved by the surface passivation strategy through appropriate treating methods . As mentioned before, the use of a 2D surface passivation layer can efficiently reduce the defect concentrations at GBs and on the film surface, which prohibited the corrosion of oxygen and water into the perovskite lattice to improve the cell performance.…”

Section: Advances In Additive Engineering For Mixed Pb–sn Narrow-band...mentioning

confidence: 97%

“…147 Zhang et al have introduced a Lewis base β-guanidinopropionic acid (GUA) as an additive into MA 0.3 FA 0.7 Pb 0.5 Sn 0.5 I 3 precursor solution and hydrazinium iodide (HAI) into isopropanol (IPA) antisolvent to passivate the perovskite film surface before and after the thermal annealing, respectively. 143 It was found that the guanidine and carboxyl functional groups in the GUA additive effectively regulated the crystallization behavior of Pb−Sn perovskites by coordinating with Pb 2+ /Sn 2+ cations and reducing the amount of deep-level antisite defects. The reducing hydrazine group in the HAI additive introduced into IPA antisolvent remarkably inhibited the Sn 2+ oxidation, effectively passivating surface defects of the perovskite film.…”

Section: Crystallization Controlmentioning

confidence: 99%

“…In addition, CF3-PA-additive-engineered all-perovskite TSCs maintained 90% of primary PCE after 600 h of MPPT operation under 1 sun irradiation in ambient air, which was much more superior to that of the pristine cell (Figure e) . Zhang et al have introduced a Lewis base β-guanidinopropionic acid (GUA) as an additive into MA 0.3 FA 0.7 Pb 0.5 Sn 0.5 I 3 precursor solution and hydrazinium iodide (HAI) into isopropanol (IPA) antisolvent to passivate the perovskite film surface before and after the thermal annealing, respectively . It was found that the guanidine and carboxyl functional groups in the GUA additive effectively regulated the crystallization behavior of Pb–Sn perovskites by coordinating with Pb 2+ /Sn 2+ cations and reducing the amount of deep-level antisite defects.…”

Section: Advances In Additive Engineering For Mixed Pb–sn Narrow-band...mentioning

confidence: 99%

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Additive Engineering for Mixed Lead–Tin Narrow-Band-Gap Perovskite Solar Cells: Recent Advances and Perspectives

Wang

Xiang

et al. 2023

Energy Fuels

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Low-cost perovskite solar cells (PSCs) with high power conversion efficiencies (PCEs) of >25% are considered as the most promising replacement for commercial silicon-based solar cells to realize a sustainable future. To break the theoretical PCE limits of single-junction PSCs, all-perovskite tandem solar cells consisting of a narrow-band-gap bottom subcell and a wide-band-gap top subcell have attracted particular attention recently. Mixed Pb–Sn perovskites with narrow band gaps have received great attention as an efficient light harvester in the bottom subcell of all-perovskite tandem solar cells as a result of the reduced toxicity, high light-absorbing capability, and matched current with the wide-band-gap top subcells. However, mixed Pb–Sn narrow-band-gap PSCs suffer from low PCEs, inferior stability, and high open-circuit voltage (V oc) loss, owing to the high defect amount and inferior perovskite film quality induced by the detrimental oxidation of Sn2+ cations and the rapid crystallization of perovskite crystals. Herein, the recent advances about the additive engineering for mixed Pb–Sn narrow-band-gap PSCs are reviewed by demonstrating the origins and unique features of Pb–Sn narrow-band-gap perovskites. Additionally, several strategies to improve PCEs and durability of Pb–Sn narrow-band-gap PSCs through additive engineering are proposed, including Sn2+ cation stabilization, heterojunction construction, crystallization control, surface/grain boundary passivation, film morphology control, carrier dynamics modulation, and gradient-distributed film formation. Furthermore, the existing challenges and future directions are also presented, aiming to provide important insights for designing and developing efficient and stable single-junction narrow-band-gap PSCs and all-perovskite tandem solar cells.

show abstract

Section: Crystallization Controlmentioning

confidence: 95%

Section: Advances In Additive Engineering For Mixed Pb–sn Narrow-band...mentioning

confidence: 97%

Section: Crystallization Controlmentioning

confidence: 99%

Section: Advances In Additive Engineering For Mixed Pb–sn Narrow-band...mentioning

confidence: 99%

See 2 more Smart Citations

Additive Engineering for Mixed Lead–Tin Narrow-Band-Gap Perovskite Solar Cells: Recent Advances and Perspectives

Wang

Xiang

et al. 2023

Energy Fuels

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“…For another example, the Sn(IV) generated during aging process can migrate from the film and leave in situ ionic vacancy sites, leading to the unsaturated coordination in crystal lattice and accelerating the film decomposition rates. [11,12] More recently, Sargent et al observed that the Sn(IV) can be initially created during the dissolution of precursors and the annealing of the film, since the conventional solvent DMSO can oxidize Sn(II) at temperatures above 100 °C. [13] Therefore, more attention should be paid to find new friendly solvents to replace DMSO and suppress the oxidation process of Sn(II) at precursor annealing or film annealing stages.…”

mentioning

confidence: 99%

DMSO‐Free Solvent Strategy for Stable and Efficient Methylammonium‐Free Sn–Pb Alloyed Perovskite Solar Cells

Zhang

Liang

Wang

et al. 2023

Advanced Energy Materials

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Harmful Sn(IV) vacancies and uncontrolled fast crystallization commonly occur in tin–lead alloyed perovskite films. The typical dimethyl sulfoxide (DMSO) processing solvent is suggested to be the primary source of problems. Here, a DMSO‐free solvent strategy is demonstrated to obtain high‐performance Cs0.25FA0.75Pb0.5Sn0.5I3 solar cells. A rational solvent selection process via Hansen solubility parameters and Gutmann's donor number shows that N,N′‐dimethylpropyleneurea (DMPU) has a strong coordinate ability to form complete complexation with organic (formamidinium iodide) and inorganic (CsI, PbI2, and SnI2) components. This treatment suppresses the iodoplumbate (PbIn2‐n) or iodostannate (SnIn2‐n) preformed in precursor solution, thereby promoting pure intermediate complexes and retarding crystallization, realizing enlarged grain size, and improved film crystallinity. Additionally, it is demonstrated that DMPU‐based solvent system can further inhibit the oxidation of Sn(II) and reduced Sn(IV) content by nearly 75% due to its superior thermal and chemical stability. This DMSO‐free strategy generates a record efficiency of 22.41%, with a Voc of 0.88 V and a FF of 82.72% for the MA‐free Sn–Pb alloyed device. The unencapsulated devices display much‐improved humidity stability at 30 ± 5% relative humidity in air for 240 h, impressive thermal stability at 85 °C for 500 h, and promote continuous operation stability at maximum power point for 150 h.

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Modulation on Electrostatic Potential of Passivator for Highly Efficient and Stable Perovskite Solar Cells

Zhang

et al. 2023

Adv Funct Materials

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The perovskite layer contains a large number of charged defects that seriously impair the efficiency and stability of perovskite solar cells (PSCs), thus it is essential to develop an effective passivation strategy to heal them. Based on theoretical calculations, it is found that enhancing the electrostatic potential of passivators can improve passivation effect and adsorption energy between charged defects and passivators. Herein, an electrostatic potential modulation (EPM) strategy is developed to design passivators for highly efficient and stable PSCs. With the EPM strategy, 1‐phenylethylbiguanide (PEBG) and 1‐phenylbiguanide (PBG) are designed. It is found that the charge distribution and electrostatic potential of phenyl‐ and phenylethyl‐ substituent on the biguanide are significantly enhanced. The N atom directly bonding to the phenyl group shows larger positive charge than that bonding to the phenylethyl group. The modulated electrostatic potential makes PBG bind stronger with the defects on perovskite surface. Based on the effective passivation of EPM, a champion efficiency of 24.67% is realized and the device retain 91.5% of its initial PCE after ≈1300 h. The promising EPM strategy, which provides a principle of passivator design and allows passivation to be controllable, may advance further optimization and application of perovskite solar cells toward commercialization.

show abstract

Suppressing Nonradiative Recombination in Lead–Tin Perovskite Solar Cells through Bulk and Surface Passivation to Reduce Open Circuit Voltage Losses

Cited by 38 publications

References 47 publications

Additive Engineering for Mixed Lead–Tin Narrow-Band-Gap Perovskite Solar Cells: Recent Advances and Perspectives

Additive Engineering for Mixed Lead–Tin Narrow-Band-Gap Perovskite Solar Cells: Recent Advances and Perspectives

DMSO‐Free Solvent Strategy for Stable and Efficient Methylammonium‐Free Sn–Pb Alloyed Perovskite Solar Cells

Modulation on Electrostatic Potential of Passivator for Highly Efficient and Stable Perovskite Solar Cells

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