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Inhibiting perovskite decomposition by a creeper-inspired strategy enables efficient and stable perovskite solar cells.

Shuxian DuHao HuangZhineng LanPeng CuiLiang LiMin WangShujie QuLuyao YanChangxu SunYingying YangXinxin WangMeicheng Li
Published in: Nature communications (2024)
The commercialization of perovskite solar cells is badly limited by stability, an issue determined mainly by perovskite. Herein, inspired by a natural creeper that can cover the walls through suckers, we adopt polyhexamethyleneguanidine hydrochloride as a molecular creeper on perovskite to inhibit its decomposition starting from the annealing process. The molecule possesses a long-line molecular structure where the guanidinium groups can serve as suckers that strongly anchor cations through multiple hydrogen bonds. These features make the molecular creeper can cover perovskite grains and inhibit perovskite decomposition by suppressing cations' escape. The resulting planar perovskite solar cells achieve an efficiency of 25.42% (certificated 25.36%). Moreover, the perovskite film and device exhibit enhanced stability even under harsh damp-heat conditions. The devices can maintain >96% of their initial efficiency after 1300 hours of operation under 1-sun illumination and 1000 hours of storage under 85% RH, respectively.
Keyphrases
  • perovskite solar cells
  • room temperature
  • high efficiency
  • solar cells
  • ionic liquid
  • single molecule
  • signaling pathway