<p>Co-deposited perovskite solar cells simplify the fabrication process, yet excessive aggregation of self-assembled molecules (SAMs) during crystallization leads to poor interfacial adhesion, thereby limiting performance and stability. This study designs an asymmetric SAM (PhBr-4PACz) with steric hindrance to mitigate self-aggregation by suppressing the face-to-face stacking of planar conjugated cores, thereby enriching the presence of co-deposited SAMs at the bottom interface with improved interfacial adhesion and coverage. Its deepened energy level by bromine group and observed p-type doping effect further promotes hole extraction&#xa0;and reduces&#xa0;non-radiative recombination. More importantly, 1-Allyl-3-vinylimidazolium chloride was introduced to seal grain boundaries by in-situ crosslinking to suppress the upward diffusion of SAMs under thermal stress&#xa0;and release residual&#xa0;stress. The optimized inverted devices based on this synergistic strategy&#xa0;achieved a certified power conversion efficiency (PCE)&#xa0;of 27.03% and retained over 96% of their initial efficiency after 2000 hours of continuous illumination at the maximum power point tracking&#xa0;(65 °C, ISOS-L-2).&#xa0;A&#xa0;certified PCE of 24.49% was also achieved for&#xa0;small-area flexible devices,&#xa0;showing&#xa0;the&#xa0;compatibility of this&#xa0;co-deposition process on different substrates.</p>

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Co-deposited inverted perovskite photovoltaics towards 27% efficiency via vertical redistribution of self-assembled-molecules and in-situ crosslinking

  • Rongshan Zhuang,
  • Anxin Sun,
  • Congcong Tian,
  • Chen Chen,
  • Shuo Liu,
  • Xueyun Wu,
  • Shulin Han,
  • Lei Cai,
  • Jinling Chen,
  • Qianwen Chen,
  • Yuyang Zhao,
  • Ran Li,
  • Teng Xue,
  • Tiantian Cen,
  • Kaibo Zhao,
  • Chun-Chao Chen

摘要

Co-deposited perovskite solar cells simplify the fabrication process, yet excessive aggregation of self-assembled molecules (SAMs) during crystallization leads to poor interfacial adhesion, thereby limiting performance and stability. This study designs an asymmetric SAM (PhBr-4PACz) with steric hindrance to mitigate self-aggregation by suppressing the face-to-face stacking of planar conjugated cores, thereby enriching the presence of co-deposited SAMs at the bottom interface with improved interfacial adhesion and coverage. Its deepened energy level by bromine group and observed p-type doping effect further promotes hole extraction and reduces non-radiative recombination. More importantly, 1-Allyl-3-vinylimidazolium chloride was introduced to seal grain boundaries by in-situ crosslinking to suppress the upward diffusion of SAMs under thermal stress and release residual stress. The optimized inverted devices based on this synergistic strategy achieved a certified power conversion efficiency (PCE) of 27.03% and retained over 96% of their initial efficiency after 2000 hours of continuous illumination at the maximum power point tracking (65 °C, ISOS-L-2). A certified PCE of 24.49% was also achieved for small-area flexible devices, showing the compatibility of this co-deposition process on different substrates.