Mixed 3D–2D Passivation Treatment for Mixed‐Cation Lead Mixed‐Halide Perovskite Solar Cells for Higher Efficiency and Better Stability

Cho, Yongyoon; Soufiani, Arman Mahboubi; Yun, Jae Sung; Kim, Jin-Cheol; Lee, Da Seul; Seidel, Jan; Deng, Xinyang; Green, Martin A.; Huang, Shujuan; Ho‐Baillie, Anita

doi:10.1002/aenm.201703392

Cited by 303 publications

(223 citation statements)

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“…[23,[33][34][35][37][38][39][40] In addition, the easy oxidation of Sn and Ge from the +2 state to the +4 state due to their high energy 5s and 4s orbitals makes them less promising for application in stable and long-term PSCs. [49] However, the highest certified PCE in a 2D-only planar PSC is 15.3%, [50] which is far below that of their 3D perovskite-based counterparts. [42,43] Furthermore, low dimensional (e.g., 2D, 1D, and 0D) perovskites have also been used to address the stability issues in PSCs.…”

mentioning

confidence: 99%

Progress of Lead‐Free Halide Double Perovskites

Igbari

Wang

Liao

2019

Advanced Energy Materials

349

305

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Although impressive performance has been obtained, PSCs are still far from commercial or real-life availability due to serious issues such as toxicity [15,16] and poor stability to heat, [17] oxygen, [18] moisture, [19,20] electric field, [21] and light. [18,22] The toxic nature of hybrid organic-inorganic lead halide perovskites has been traced to the presence of Pb in its chemical composition. [15,16,[23][24][25] Pb 2+ readily dissolves in water (e.g., rain water) to form a toxic solution capable of causing serious environmental pollution, harmful to human beings and the ecosystem. Besides their sensitivity to moisture, oxygen, light, electric field, or thermal stress, an existing self-degradation pathway [26,27] is also a big issue in hybrid organic-inorganic lead halide perovskites. Mixed-halide and mixed-cation perovskites have been investigated to address these issues. [28][29][30][31][32] The group IV elements, tin (Sn) [23,[33][34][35] and germanium (Ge), [34,36] have been employed as the replacements for Pb. However, the device performance through this approach has fallen short of the Pb-based ones. For example, the PCEs reported for Sn-based perovskite solar cells are usually less than 10%. [23,[33][34][35][37][38][39][40] In addition, the easy oxidation of Sn and Ge from the +2 state to the +4 state due to their high energy 5s and 4s orbitals makes them less promising for application in stable and long-term PSCs. [41] High throughput calculations also demonstrate that these substitutions are likely to compromise the ideal optoelectronic properties of MAPbI 3 . [42,43] Furthermore, low dimensional (e.g., 2D, 1D, and 0D) perovskites have also been used to address the stability issues in PSCs. [44][45][46][47][48] Recently, a stabilized PCE of 21.7% resulting from a 2D/3D bilayer PSC was reported. [49] However, the highest certified PCE in a 2D-only planar PSC is 15.3%, [50] which is far below that of their 3D perovskite-based counterparts. It thus stimulates the interest to develop new classes of materials which can solve the issues of toxicity and stability while still maintaining the fascinating properties of lead-based perovskite materials.Recent theoretical calculations demonstrate that a halide double perovskite structure, A 2 B′B″X 6 , which could be formed through a replacement of two toxic Pb 2+ in the crystal lattice with a pair of nontoxic heterovalent (i.e., monovalent and trivalent) metal cations, is a promising alternative to realize high-performance, lead-free, and stable PSCs. [51,52] Although, spectroscopic limited maximum efficiency (SLME) calculations revealed an efficiency limit less than 8% for the most prominent member www.advancedsciencenews.com double perovskites with a vacancy ordered structure. [88] In particular, the unit cell axis of Cs 2 AgBiBr 6 is given to be ≈11.25 Å, [25] which is two times larger than that of MAPbBr 3 (≈5.92 Å). [89] Both Ag + and Bi 3+ occupy the B-site of the crystal lattice with slightly varied metal-halide bond lengths. The dissimilar bond lengths st...

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confidence: 99%

Progress of Lead‐Free Halide Double Perovskites

Igbari

Wang

Liao

2019

Advanced Energy Materials

349

305

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“…The increased R ct and R rec of 2D/3D MHP indicated the roles of 2D MHPs in passivating surface traps and improving charge transfer . Similarly, other 2D MHPs including (i‐BA) 2 PbI 4 , (AVA) 2 PbI 4 , and MA 3 Bi 2 I 9 were also produced on 3D MHPs and exhibited improved performance and stability …”

Section: Interfacial Modification Layersmentioning

confidence: 89%

“…XRD measurement is a structure‐monitoring method used to investigate the effect of interface engineering on the stability of the MHP layer. For example, XRD was used to demonstrate the excellent moisture stability of MHPs after 2D MHP interface modification by monitoring PbI 2 and yellow phase characteristic patterns …”

Section: Interface Characterizationsmentioning

confidence: 99%

Interface Engineering in n‐i‐p Metal Halide Perovskite Solar Cells

2018

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Recent years have witnessed continuous progress in metal halide perovskite (MHP) solar cells with a certified power conversion efficiency (PCE) exceeding 22%. However, the commercialization of MHP solar cells continues to encounter various challenges including stabilization, scalability and repeatability. Of all problems related to MHP materials, interface recombination is the most prominent, resulting in severe PCE loss within a short time. Fortunately, interface engineering has been identified as an efficient means of achieving better energy‐level alignment, reduced charge recombination, trap passivation, elimination of photocurrent hysteresis, and enhanced long‐term device stability. This review examines the relationship between specific interface modification layers and their roles in interface engineering based on device physics, revealed by several characterization methods. The latest research advances in interface modification layers according to their roles and properties are also summarized.

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Section: Surface Passivation By Organic Halide Saltmentioning

confidence: 99%

“…2019, 2, 93-106 of FAPbBr 3-x I x was formed after reaction with the excess of PbI 2 present on the surface. [73] Wang et al reported growth of 2D PEA 2 PbI 4 capping layers on top of 3D perovskite film, which resulted in an enhanced Voc and drastically improved the stability of PSCs without compromising their high performance ( Figure 12b). The preparation method is shown in Figure 12a.…”

Section: Surface Passivation By Organic Halide Saltmentioning

confidence: 99%

Recent Progress in High‐efficiency Planar‐structure Perovskite Solar Cells

Zhao

Chu

et al. 2019

Energy & Environ Materials

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Lead halide perovskite owns charge diffusion length in micrometer range, which makes the planar-structure solar cells possible. The simple and lowtemperature process of planar devices makes it very promising. The power conversion efficiency of planar perovskite solar cells has increased from 1.8% to 23.7% in past several years, which can compete with the mesoporous structure counterpart. In this minireview, recent progress in high-efficiency planar perovskite solar cells will be summarized. REVIEW Perovskite Solar CellsEnergy Environ. Mater. 2019, 2, 93-106

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Mixed 3D–2D Passivation Treatment for Mixed‐Cation Lead Mixed‐Halide Perovskite Solar Cells for Higher Efficiency and Better Stability

Cited by 303 publications

References 61 publications

Progress of Lead‐Free Halide Double Perovskites

Progress of Lead‐Free Halide Double Perovskites

Interface Engineering in n‐i‐p Metal Halide Perovskite Solar Cells

Recent Progress in High‐efficiency Planar‐structure Perovskite Solar Cells

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