Successive surface engineering of TiO<sub>2</sub> compact layers via dual modification of fullerene derivatives affording hysteresis-suppressed high-performance perovskite solar cells - Concepedia

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Successive surface engineering of TiO<sub>2</sub> compact layers via dual modification of fullerene derivatives affording hysteresis-suppressed high-performance perovskite solar cells

78

Citations

60

References

2016

Year

Weiran Zhou, Jieming Zhen, Qing Liu, Zhimin Fang, Dan Li, Pengcheng Zhou, Tao Chen, Shangfeng Yang

Journal of Materials Chemistry A

EngineeringFullerene DerivativesHalide PerovskitesDual ModificationPhotovoltaicsDramatic Efficiency EnhancementSolar Cell StructuresSuccessive Surface EngineeringMaterials ScienceElectrical EngineeringOxide ElectronicsPerovskite MaterialsMicroelectronicsLead-free PerovskitesSurface CharacterizationSuppressed-hysteresis Current–voltage ResponsePerovskite Solar CellSurface AnalysisSurface ScienceApplied PhysicsSurface EngineeringSolar CellsSurface ProcessingSolar Cell Materials

Abstract

A new successive surface engineering method <italic>via</italic> a dual modification of TiO<sub>2</sub> compact layer by PC<sub>61</sub>BM and C<sub>60</sub>-ETA was developed, affording dramatic efficiency enhancement with suppressed-hysteresis current–voltage response.

References

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