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    Journals >Acta Photonica Sinica >Volume 50 >Issue 12 >Page 1223001 > Article
    • Acta Photonica Sinica
    • Vol. 50, Issue 12, 1223001 (2021)
    Optimizing Processes of Silicon Heterojunction Solar Cell
    Xisheng ZHANG*, Chunyu YAN, Jingzhou WANG, Ziwei MA, and Chenzhong YAO
    Author Affiliations
  • Department of Physics and Electronic Engineering, Yuncheng University, Yuncheng , Shanxi 044000, China
    • show less
    DOI: 10.3788/gzxb20215012.1223001 Cite this Article
    Xisheng ZHANG, Chunyu YAN, Jingzhou WANG, Ziwei MA, Chenzhong YAO. Optimizing Processes of Silicon Heterojunction Solar Cell[J]. Acta Photonica Sinica, 2021, 50(12): 1223001 Copy Citation Text show less
    References

    [1] D JULIE, J QUENTIN, C JEAN et al. 23.5%-efficient silicon heterojunction silicon solar cell using molybdenum oxide as hole-selective contact. Nano Energy, 70, 104495(2020).

    [2] A DESCOEUDRES, J HORZELl, B PAVIET‐SALOMON et al. The versatility of passivating carrier‐selective silicon thin films for diverse high‐efficiency screen‐printed heterojunction‐based solar cells. Progress in Photovoltaics: Research and Applications, 28, 569-577(2020).

    [3] F GERENTON, J EYMARD, S HARRISON et al. Analysis of edge losses on silicon heterojunction half solar cells. Solar Energy Materials & Solar Cells, 204, 110213(2020).

    [4] K YOSHIKAWA, H KAWASAKI, W YOSHIDA et al. Silicon heterojunction solar cell with interdigitated back contacts for a photoconversion efficiency over 26%. Nature Energy, 2, 817032(2017).

    [5] M TAGUCHI, A YANO, S TOHODA et al. 24.7% record efficiency HIT solar cell on thin silicon wafer. IEEE Journal of Photovoltaics, 4, 96-99(2014).

    [6] Zhenhai YANG, Xi YANG, Hao LIN et al. The role of transition region charges between dopant-free asymmetric heterocontacts in interdigitated back contact silicon heterojunction solar cells. Solar Energy, 188, 1201-1208(2019).

    [7] Zhenhai YANG, Hao LIN, Jiang SHENG et al. Design principles of silicon heterojunction solar cells with dopant-free interdigitated back contacts. Solar RRL, 3, 1900230(2019).

    [8] S D WOLF, M KONDO. Abruptness of a-Si:H/c-Si interface revealed by carrier lifetime measurements. Applied Physics Letters, 90, 042111(2007).

    [9] L KORTE, E CONRAD, H R ANGERMANN et al. Advances in a-Si: H/c-Si heterojunction solar cell fabrication and characterization. Solar Energy Materials & Solar Cells, 93, 905-910(2009).

    [10] S D WOLF, A DESCOEUDRES, Z HOLMAN et al. High-efficiency silicon heterojunction solar cells: a review. Green, 2, 7-24(2012).

    [11] T KOIDA, H FUJIWARA, M KONDO. Reduction of optical loss in hydrogenated amorphous silicon/crystalline silicon heterojunction solar cells by high-mobility hydrogen-doped In2O3 transparent conductive oxide. Applied Physics Express, 1, 04501(2008).

    [12] B STEGEMANNA, J KEGEL, M MEWS et al. Evolution of the charge carrier lifetime characteristics in crystalline silicon wafers during processing of heterojunction solar cells. Energy Procedia, 55, 219-228(2014).

    [13] Y NISHIMOTO, K NAMBA. Investigation of texturization for crystalline silicon solar cells with sodium carbonate solutions. Solar Energy Materials & Solar Cells, 61, 393-402(2000).

    [14] Yueke DING, Shihua HUANG. Study on passivation of monocrystalline silicon by tandem hydrogenated amorphous silicon film. Acta Photonica Sinica, 50, 0331001(2021).

    [15] C LEENDERTZ, N MINGIRULLI, T SCHULZE et al. Discerning passivation mechanisms at a-Si:H/c-Si interfaces by means of photoconductance measurements. Applied Physics Letters, 98, 202108(2011).

    [16] J KEGEL, H ANGERMKANN, U STURZEBECHER et al. IPA-free texturization of n-type Si wafers: correlation of optical, electronic and morphological surface properties. Energy Procedia, 38, 833-842(2013).

    [17] S OLIBET, C MONACHON, A HESSLER-WYSER et al. Textured silicon heterojunction solar cells with over 700 mV open-circuit voltage studied by transmission electron microscopy, 1140(2008).

    [18] B STEGEMANN, J KEGEL, M MEWS et al. Passivation of textured silicon wafers: influence of pyramid size distribution, a-Si:H deposition temperature, and post-treatment. Energy Procedia, 38, 881-889(2013).

    [19] S D WOLF, H FUJIWARA, M KONDO. Impact of annealing on passivation of a-Si:H / c-Si heterostructures(2008).

    [20] D ZHANG, D DELIGIANNIS, G PAPAKONSTANTINOU et al. Optical enhancement of silicon heterojunction solar cells with hydrogenated amorphous silicon carbide emitter. IEEE Journal of Photovoltaics, 4, 1326-1330(2014).

    [21] A DESCOEUDRES, Z C HOLMAN, L BARRAUD et al. >21% efficient silicon heterojunction solar cells on n- and p-Type wafers compared. IEEE Journal of Photovoltaics, 3, 83-89(2013).

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    Xisheng ZHANG, Chunyu YAN, Jingzhou WANG, Ziwei MA, Chenzhong YAO. Optimizing Processes of Silicon Heterojunction Solar Cell[J]. Acta Photonica Sinica, 2021, 50(12): 1223001
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