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

Yang, Zhi; Dou, Jinjuan; Wang, Minqiang

doi:10.1002/solr.201800177

Cited by 58 publications

(55 citation statements)

References 139 publications

(199 reference statements)

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“…This result proves that the perovskite layers on the different substrates share the same properties. The intensity of the fluorescence emission reflects the efficiency of carrier extraction; a weak fluorescence indicates a fast charge transfer, which reduces the radiative recombination . This phenomenon is the result of a highly precise energy level match and improved electrical conductivity.…”

Section: Resultsmentioning

confidence: 99%

Low‐Temperature‐Processed Zr/F Co‐Doped SnO₂ Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Tian

Zhang

et al. 2020

Solar RRL

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The energy band position and conductivity of electron transport layers (ETLs) are essential factors that restrict the efficiency of planar perovskite solar cells (p‐PSCs). Tin oxide (SnO2) has become a primary material in ETLs due to its mild synthesis condition, but its low conduction band position and limited intrinsic carriers are disadvantageous in electron transport. To solve these problems, this work exquisitely designs a Zr/F co‐doped SnO2 ETL. The doping of Zr can raise the conduction band of SnO2, which reduces the energy barrier in electron extraction and inhibits the interface recombination between the ETL and perovskite. The open‐circuit voltage (VOC) of p‐PSCs consequently increases. F− doping belongs to n‐type doping. Thus, it equips SnO2 with a large number of free electrons and improves the conductivity of the ETL and short‐circuit current (JSC). The device based on Zr/F co‐doped ETL achieves a high efficiency of 19.19% and exhibits a reduced hysteresis effect, which is more satisfactory than that of a pristine device (17.35%). Overall, this research successfully adjusts the energy band match and boosts the conductivity of ETL via Zr/F co‐doping. The results provide an effective strategy for fabricating high‐efficiency p‐PSCs.

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Section: Resultsmentioning

confidence: 99%

Low‐Temperature‐Processed Zr/F Co‐Doped SnO₂ Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Tian

Zhang

et al. 2020

Solar RRL

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“…Different kinds of functional molecules including Lewis acid and base, alkylammonium halide, and wide bandgap and hydrophobic polymers can passivate perovskite surface acting as interfacial modification layers. [ 2,18–27 ] However, it is still difficult to accurately identify defect types including Pb 2+ /halide vacancies, interstitial Pb 2+ /halides, and undercoordinated Pb 2+ /halides for these multicomponent perovskites. [ 11,28–30 ] Therefore, identifying defect types and adopting suitable passivators are crucial not only to boost the efficiency but also to slow down the moisture degradation.…”

Section: Introductionmentioning

confidence: 99%

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

Yang

Dou

Kou

et al. 2020

Adv Funct Materials

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175

139

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Multiple-cation lead mixed-halide perovskites (MLMPs) have been recognized as ideal candidates in perovskite solar cells in terms of high efficiency and stability due to decreased open-circuit voltage loss and suppressed yellow phase formation. However, they still suffer from an unsatisfactory long-term moisture stability. In this study, phosphorus-containing Lewis acid and base molecules are employed to improve device efficiency and stability based on their multifunction including recombination reduction, phase segregation suppression, and moisture resistance. The strong fluorine-containing Lewis acid treatment can achieve a champion PCE of 22.02%. Unencapsulated and encapsulated devices retain 63% and 80% of the initial efficiency after 14 days of aging under 75% and 85% relative humidity, respectively. The better passivation of Lewis acid implies more halide defects than Pb defects at the MLMP surface. This unbalanced defect type results from phase segregation that is the synergistic effect of Cs and halide ion migrations. Identifying defect type based on different passivation effects is beneficial to not only choose suitable passivators to boost the efficiency and slow down the moisture degradation of MLMP solar cells, but also to understand the mechanism of defect-assisted moisture degradation.

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“…The lifetime of photogenerated charge carriers (electrons and holes) in perovskite is approximately balanced, normally at a timescale of 10–100 ns in multicrystalline perovskite films and >1000 ns in single crystal of perovskite . Under the driving force of concentration gradient or build‐in potential, the photogenerated carriers will diffuse or migrate to the interfaces; furthermore, the carriers will be selectively separated at the interlayers at a typical timescale of <10 ns; afterward, the free carriers will be collected through the interfacial layers at a typical timescale of <10 μs; at the meantime, before the carriers reach the electrodes, interfacial recombination will compete with the positive transportation at a typical timescale of 1–1000 μs, leading to photocurrent and photovoltage losses. In addition, the back charge transfer at the interfaces occurred at a timescale of 1 μs to 1 ms, resulting in photocurrent loss.…”

Section: Importance Of Interfacial Engineering In Pscsmentioning

confidence: 99%

“…The crystallographic stability and the probable crystal structure of halide perovskite can be predicted by Goldschmidt tolerance factor ( t ) and octahedral factor ( μ ), which are defined by the following formulas

t = \frac{R_{normalA} + R_{normalX}}{\sqrt{2} (R_{normalB} + R_{normalX})}

μ = \frac{R_{B}}{R_{X}}

where R A , R B , and R X are the ionic radii of A, B cations and X anion, respectively. If the calculated results are located in the range of 0.81 < t < 1.11 and 0.44 < μ < 0.90, halide perovskite is favorable to form a 3D‐crystal structure . It is reported that an ideal cubic structure will be preferably formed when the value of t locates at a narrower range of 0.89–1.0, whereas a less symmetric tetragonal or orthorhombic structure may be presented if the value of t is lower than this range .…”

Section: Introductionmentioning

confidence: 98%

“…Photoactive halide perovskites normally exhibit a 3D crystal structure (Figure ) with a characteristic chemical formula of ABX 3 , where A is a monovalent cation of methylammonium (CH 3 NH 3 + , denoted as MA + ), formamidinium (HC(NH 2 ) 2 + , denoted as FA + ), cesium (Cs + ), or rubidium (Rb + ), B is a divalent metal cation (Pb 2+ or Sn 2+ ), and X is a halide anion (Cl − , Br − , or I − ) . The crystallographic stability and the probable crystal structure of halide perovskite can be predicted by Goldschmidt tolerance factor ( t ) and octahedral factor ( μ ), which are defined by the following formulas

t = \frac{R_{normalA} + R_{normalX}}{\sqrt{2} (R_{normalB} + R_{normalX})}

μ = \frac{R_{B}}{R_{X}}

where R A , R B , and R X are the ionic radii of A, B cations and X anion, respectively.…”

Section: Introductionmentioning

confidence: 99%

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Review on Practical Interface Engineering of Perovskite Solar Cells: From Efficiency to Stability

et al. 2019

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Exceptionally high efficiencies for organic–inorganic hybrid perovskite solar cells (PSCs) have been achieved. However, their operational stability still needs to be improved. The intrinsic instability of halide perovskites caused by the presence of volatile organic cations, as well as the degradation of hybrid perovskites induced by the adverse permeation of environmental water (H2O)/oxygen (O2) and the undesired ion diffusion or migration are the major reasons. Beyond strengthening perovskites themselves, interface engineering is now regarded as a valid strategy to prolong device lifetime by preventing the undesired degradation pathways. This comprehensive review highlights the utilization of practical interface engineering for enhancing the efficiency and stability of organic–inorganic lead halide PSCs. First, the impacts of interface design on the energy‐level alignment and carrier dynamics are overviewed. Second, recent progresses on the development of interfacial materials for simultaneously achieving high efficiency and stability of PSCs are summarized. At last, the interfacial layer design principles along with future outlook of this rapidly developing field are discussed.

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

Cited by 58 publications

References 139 publications

Low‐Temperature‐Processed Zr/F Co‐Doped SnO₂ Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Low‐Temperature‐Processed Zr/F Co‐Doped SnO₂ Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

Review on Practical Interface Engineering of Perovskite Solar Cells: From Efficiency to Stability

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

Cited by 58 publications

References 139 publications

Low‐Temperature‐Processed Zr/F Co‐Doped SnO2 Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Low‐Temperature‐Processed Zr/F Co‐Doped SnO2 Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Multifunctional Phosphorus‐Containing Lewis Acid and Base Passivation Enabling Efficient and Moisture‐Stable Perovskite Solar Cells

Review on Practical Interface Engineering of Perovskite Solar Cells: From Efficiency to Stability

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Low‐Temperature‐Processed Zr/F Co‐Doped SnO₂ Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells

Low‐Temperature‐Processed Zr/F Co‐Doped SnO₂ Electron Transport Layer for High‐Efficiency Planar Perovskite Solar Cells