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Free-standing ultrathin silicon wafers and solar cells through edges reinforcement

Author

Listed:
  • Taojian Wu

    (Shanghai Jiao Tong University)

  • Zhaolang Liu

    (Shenzhen Campus of Sun Yat-sen University)

  • Hao Lin

    (Shenzhen Campus of Sun Yat-sen University
    Sun Yat-sen University)

  • Pingqi Gao

    (Shenzhen Campus of Sun Yat-sen University
    Sun Yat-sen University
    Changzhou University)

  • Wenzhong Shen

    (Shanghai Jiao Tong University)

Abstract

Crystalline silicon solar cells with regular rigidity characteristics dominate the photovoltaic market, while lightweight and flexible thin crystalline silicon solar cells with significant market potential have not yet been widely developed. This is mainly caused by the brittleness of silicon wafers and the lack of a solution that can well address the high breakage rate during thin solar cells fabrication. Here, we present a thin silicon with reinforced ring (TSRR) structure, which is successfully used to prepare free-standing 4.7-μm 4-inch silicon wafers. Experiments and simulations of mechanical properties for both TSRR and conventional thin silicon structures confirm the supporting role of reinforced ring, which can share stress throughout the solar cell preparation and thus suppressing breakage rate. Furthermore, with the help of TSRR structure, an efficiency of 20.33% (certified 20.05%) is achieved on 28-μm silicon solar cell with a breakage rate of ~0%. Combining the simulations of optoelectrical properties for TSRR solar cell, the results indicate high efficiency can be realized by TSRR structure with a suitable width of the ring. Finally, we prepare 50 ~ 60-μm textured 182 × 182 mm2 TSRR wafers and perform key manufacturing processes, confirming the industrial compatibility of the TSRR method.

Suggested Citation

  • Taojian Wu & Zhaolang Liu & Hao Lin & Pingqi Gao & Wenzhong Shen, 2024. "Free-standing ultrathin silicon wafers and solar cells through edges reinforcement," Nature Communications, Nature, vol. 15(1), pages 1-11, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-48290-5
    DOI: 10.1038/s41467-024-48290-5
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    References listed on IDEAS

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    1. Wenzhu Liu & Yujing Liu & Ziqiang Yang & Changqing Xu & Xiaodong Li & Shenglei Huang & Jianhua Shi & Junling Du & Anjun Han & Yuhao Yang & Guoning Xu & Jian Yu & Jiajia Ling & Jun Peng & Liping Yu & B, 2023. "Flexible solar cells based on foldable silicon wafers with blunted edges," Nature, Nature, vol. 617(7962), pages 717-723, May.
    2. Hao Lin & Miao Yang & Xiaoning Ru & Genshun Wang & Shi Yin & Fuguo Peng & Chengjian Hong & Minghao Qu & Junxiong Lu & Liang Fang & Can Han & Paul Procel & Olindo Isabella & Pingqi Gao & Zhenguo Li & X, 2023. "Silicon heterojunction solar cells with up to 26.81% efficiency achieved by electrically optimized nanocrystalline-silicon hole contact layers," Nature Energy, Nature, vol. 8(8), pages 789-799, August.
    3. Sangmoo Jeong & Michael D. McGehee & Yi Cui, 2013. "All-back-contact ultra-thin silicon nanocone solar cells with 13.7% power conversion efficiency," Nature Communications, Nature, vol. 4(1), pages 1-7, December.
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