Perovskite-perovskite-silicon triple junction solar cells with improved carrier and photon management

  1. Kerem Artuk
  2. Deniz Turkay
  3. Austin G. Kuba
  4. Stefan Riemelmoser
  5. Julian Steele
  6. Hugo Quest
  7. Michele De Bastiani
  8. Jonas Diekmann
  9. Julien Hurni
  10. Chiara Ongaro
  11. Mostafa Othman
  12. Maryamsadat Heydarian
  13. Oliver Fischer
  14. Huagui Lai
  15. Stefan Zeiske
  16. Rafael López-Arteaga
  17. Mounir D. Mensi
  18. Felipe Saenz
  19. Lisa Champault
  20. Hilal Aybike Can
  21. Mohammad Reza Golobostanfard
  22. Umang Desai
  23. Paul Remondeau
  24. Eduardo Solano
  25. Antonin Faes
  26. Fan Fu
  27. Martin Schubert
  28. Florian Schindler
  29. Bin Chen
  30. Alfredo Pasquarello
  31. Edward Sargent
  32. Aicha Hessler-Wyser
  33. Giuseppe Portale
  34. Quentin Jeangros
  35. Christophe Ballif
  36. Christian Wolff
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Abstract

Perovskite–silicon triple-junction photovoltaics offer efficiency gains beyond dual-junction devices, but at the expense of added complexity. Here, we address two main challenges in perovskite-silicon-based triple-junction solar cells: reduced open-circuit voltage in the wide-bandgap top-cell and limited current density in the middle-cell. Additive engineering with 4-hydroxybenzylamine modulates the crystallization dynamics of the top-cell absorber and suppresses bulk recombination, enabling open-circuit voltages up to 1.405 V. The three-step-manufactured lead-halide middle-cell absorbers result in an increasing thickness and a reduced bandgap, thereby boosting the current density. Low-refractive-index SiOx nanoparticles accumulated in the front valleys of the textured silicon bottom-cell act as a middle-reflector, enhancing light absorption in the middle-cell. These innovations are then combined in 1-cm2 perovskite-perovskite-silicon devices, reaching a steady-state efficiency of 30.5%.

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  1. Version published to 10.21203/rs.3.rs-7077073/v1 on Research Square