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Research progress of crystalline silicon solar cells with dopant-free asymmetric heterocontacts

Zhao Sheng-Sheng Xu Yu-Zeng Chen Jun-Fan Zhang Li Hou Guo-Fu Zhang Xiao-Dan Zhao Ying

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Research progress of crystalline silicon solar cells with dopant-free asymmetric heterocontacts

Zhao Sheng-Sheng, Xu Yu-Zeng, Chen Jun-Fan, Zhang Li, Hou Guo-Fu, Zhang Xiao-Dan, Zhao Ying
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  • Due to the rapid development of dopant free asymmetric heterogeneous contacts in recent years, the theoretical conversion efficiency can reach 28%, which has large room for development and has attracted one’s attention. With the expectation of low cost and green pollution-free solar cell, the traditional crystalline silicon solar cell has many limitations due to its high equipment cost and flammable and explosive raw materials. It greatly increases the necessity of research and development of new solar cells with no doping and asymmetric heterogeneous contacts. The new solar cell is safe and environmental friendly due to the multi-faceted advantages of dopant-free asymmetric heterogeneous contact (DASH) solar cells constructed by transition metal oxide (TMO): the TMO has been widely studied as an alternative option, because of its wide band gap, little parasitic absorption, as well as repressed auger recombination, and conducing to the increase of the short-circuit current density of the solar cells; the DASH solar cell has high efficiency potential, its theoretical efficiency has reached 28%, and it can be produced by low-cost technology such as thermal evaporation or solution method; it always avoids using flammable, explosive and toxic gases in the manufacturing process. Our group proposed using MoOx as a hole selective contact and ZnO as an electron selective contact to construct a new and efficient DASH solar cell. It has achieved a conversion efficiency of 16.6%. Another device, in which MoOx is used as the hole selective contact and n-nc-Si:H as the electron selective, was fabricated, and its efficiency has reached 14.4%. In order to further speed up the research progress of the dopant-free asymmetric heterogeneous contact crystalline silicon solar cell, the development status is reviewed, and the basic principle and preparation technology of selective transport of transition metal oxide (TMO) carriers are discussed. And the effect of the hole transport layer, the electron transport layer and the passivation layer on the performance of the TMO dopant-free asymmetric heterogeneous contact (DASH) solar cells are discussed in order to have an in-depth understanding of the working mechanism and material selection of the battery, thereby providing guidance in preparing new and efficient DASH solar cells.
      Corresponding author: Hou Guo-Fu, gfhou@nankai.edu.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant Nos. 61474066, 61504069), the Natural Science Foundation of Tianjin, China (Grant No. 15JCYBJC21200), the Key Laboratory of Optical Information Technical Science, Ministry of Education of China (Grant No. 2017KFKT015), and the Fundamental Research Fund for the Central Universities, China.
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  • 图 1  钝化接触太阳电池结构及载流子输运方式[13]

    Figure 1.  Passivated contact solar cell structure and carrier transport mode[13].

    图 2  能带结构示意图

    Figure 2.  energy band structure diagram.

    图 3  NiO/c-Si/TiO2结构太阳电池示意图[9]

    Figure 3.  Schematics of the NiO/c-Si/TiO2 solar cell structure[9].

    图 4  (a) MoOx/c-Si异质结太阳电池结构的示意图; (b)通过扫描电子显微镜成像的横截面图[16]

    Figure 4.  (a) Schematics of the MoOx/n-Si heterojunction solar cell structure; (b) cross section imaged by scanning electron microscopy[16].

    图 5  全背接触结构的太阳电池示意图[10]

    Figure 5.  Schematics of the full back contact solar cell structure[10].

    图 6  (a)BackPEDOT太阳电池正面; (b)BackPEDOT太阳电池横截面示意图[39]

    Figure 6.  (a)BackPEDOT solar cell front; (b) schematic cross-section of the BackPEDOT solar cell[39].

    图 7  MLBC太阳电池结构[11]

    Figure 7.  The structure of MLBC solar cell[11].

    图 8  使用MoOx作为空穴选择性接触的硅异质结电池结构 (a)n-a-Si:H作为电子选择性接触; (b)ZnO:B作为电子选择性接触[47]

    Figure 8.  Silicon heterojunction cell structure using MoOx as hole selective contact; (a) n-a-Si:H as electron selective contact; (b) ZnO:B as electron selectivecontact[47].

    图 9  采用MoOx作为空穴选择性接触, 分别n+-a-Si:H和ZnO:B作为电子选择性接触的硅异质结电池特性 (a)J-V曲线; (b)EQE曲线[47]

    Figure 9.  Characteristics of silicon heterojunction cells with MoOx as hole selective contact, n+-a-Si:H and ZnO:B as electron selective contact respectively: (a) J-V curve; (b) EQE curve[47].

    图 10  (a)在c-Si上沉积MoOx薄膜的横截面图像; (b)MoOx和c-Si的交界处图像; (c)EDS线扫描区域的横截面STEM图像; (d)使用EDS线测量每个元素的组成分布, 显示在MoOx和c-Si之间形成薄的SiOx[35]

    Figure 10.  (a) The image of an as-deposited MoOx film on c-Si; (b) the image of the MoOx and c-Si interface; (c) cross-sectional STEM image for the region of the EDS line scan; (d) compositional distribution of each element measured using the EDS line scan showing a thinSiOx layer formed between the MoOx and the c-Si[35].

    表 1  基于TMO载流子选择性接触的硅异质结太阳电池研究现状

    Table 1.  Summary of Silicon Heterojunction Solar Cells Based on TMO Carrier Selective Contact.

    Device ArchitectureJsc/mA·cm-2Voc/mVFFEfficiency/%Reference(Year)
    MoOx/nc-Si/n a-Si:H37.85806514.3Battaglia et al.[16](2014)
    MoOx/i a-Si:H/c-Si/i a-Si:H/n a-Si:H38.6725.480.3622.5Jonas et al.[26](2015)
    p+-Si/p-c-Si/MoOx376167216.4Bullock et al.[43](2015)
    p+-Si/n-c-Si/TiO239.263979.119.8Yang et al.[44](2015)
    MoOx/a-Si:H(i)/c-Si/a-Si:H(i)/LiFx37.07716.473.1519.42Bullock et al.[8](2016)
    MoOx/ia-Si:H/nc-Si/ia-Si:H/n a-Si:H39.471167.218.8Battaglia et al.[17](2016)
    V2Ox/c-Si/ n a-Si:H34.460675.315.7Gerling et al.[15](2016)
    MoOx/c-Si/ n a-Si:H34.158168.813.6Gerling et al.[15](2016)
    WOx/c-Si/ n a-Si:H33.35776512.5Gerling et al.[15](2016)
    p+-Si/n-c-Si/SiO2/TiO239.56508020.5Yang et al.[45](2016)
    V2Ox /Au /V2Ox38.765175.4919.02Wu et al.[11](2017)
    p+-Si/n-c-Si/MgOx39.562880.620Wan et al.[46](2017)
    MoOx/i a-Si:H/c-Si/i a-Si:H/BZO38.159972.716.6Wang et al.[47](2017)
    MoOx/a-Si:H(i)/c-Si/a-Si:H(i)/TiOx/LiF38.470676.220.7Bullock et al.[32](2018)
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  • [1]

    沈文忠, 李正平 2014 硅基异质结太阳电池物理与器件 (北京: 科学出版社)第2—4页

    Shen W Z, Li Z P 2014 Physics and Devices of Silicon Heterojunction Solar Cells (Beijing: Science Press) pp2–4 (in Chinese)

    [2]

    Yoshikawa K, Kawasaki H, Yoshida W, Irie T, Konishi K, Nakano K, Uto T, Adachi D, Kanematsu M, Uzu H 2017 Nature Energy 2 17032Google Scholar

    [3]

    肖友鹏, 高超, 王涛, 周浪 2017 66 158801Google Scholar

    Xiao Y P, Gao C, Wang T, Zhou L 2017 Acta Phys. Sin. 66 158801Google Scholar

    [4]

    Feldmann F, Simon M, Bivour M, Reichel C 2014 Appl. Phys. Lett. 104 1184

    [5]

    Richter A, Benick J, Feldmann F, Fell A, Hermle M, Glunz S W 2019 Sol. Energy Mater. Sol. Cells (in Press)

    [6]

    Gao P, Yang Z, He J, Yu J, Liu P, Zhu J, Ge Z, Ye J 2018 Adv. Sci. 5

    [7]

    Melskens J, Loo B W H V D, Macco B, Black L E, Smit S, Kessels W M M 2018 IEEE J. Photovoltaics 8 373Google Scholar

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    Bullock J, Hettick M, Geissbühler J, Ong A J, Allen T, Sutterfella C M, Chen T, Ota H, Schaler E W, Wolf S D 2016 Nature Energy 1 15031Google Scholar

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    Imran H, Abdolkader T M, Butt N Z 2016 IEEE Trans. Electron Devices 63 3584Google Scholar

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    Cuevas A, Allen T, Bullock J, Wan Y, Zhang X 2014 Photovoltaic Specialist Conference pp1–6

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    Würfel U, Cuevas A, Würfel P 2014 IEEE J. Photovoltaics 5 461

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    Gerling L G, Mahato S, Morales-Vilches A, Masmitja G, Ortega P, Voz C, Alcubilla R, Puigdollers J 2016 Sol. Energy Mater. Sol. Cells 145 109Google Scholar

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    Vijayan R A, Essig S, Wolf S D, Ramanathan B G, Löper P, Ballif C, Varadharajaperumal M 2018 IEEE J. Photovoltaics 8 473Google Scholar

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    Yin X, Yao Z, Luo Q, Dai X, Zhou Y, Zhang Y, Zhou Y, Luo S, Li J, Wang N 2017 ACS Appl. Mater. Interfaces 9 2439Google Scholar

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    Chen W, Wu Y, Yue Y, Liu J, Zhang W, Yang X, Chen H, Bi E, Ashraful I, Grätzel M 2015 Science 350 944Google Scholar

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    Yang X, Weber K, Hameiri Z, De Wolf S 2017 Prog. Photovoltaics Res. Appl. 25

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    Bullock J, Wan Y, Xu Z, Essig S, Hettick M, Wang H, Ji W, Boccard M, Cuevas A, Ballif C 2018 ACS Energy Lett. 3

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    Khan F, Baek S H, Kim J H 2015 Nanoscale 8 1007

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    Tong J, Wan Y, Cui J, Lim S, Song N, Lennon A 2017 Appl. Surface Science 423

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    Zhang C, Zhang Y, Guo H, Jiang Q, Dong P, Zhang C 2018 Energies 11

    [38]

    He L, Jiang C, Wang H, Lai D, Rusli 2012 Appl. Phys. Lett. 100 12344

    [39]

    Zielke D, Niehaves C, Lövenich W, Elschner A, Hörteis M, Schmidt J 2015 Energy Procedia 77 331Google Scholar

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    Ling Z, He J, He X, Liao M, Liu P, Yang Z, Ye J, Gao P 2017 IEEE J. Photovoltaics 1

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    Tong H, Yang Z, Wang X, Liu Z, Chen Z, Ke X, Sui M, Tang J, Yu T, Ge Z 2018 Adv. Energy Mater. 1702921

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    Bao J, Wu W, Liu Z, Shen H 2016 AIP Adv. 6 96

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    Yang X, Weber K Photovoltaic Specialist Conference pp1-4

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    Yang X, Zheng P, Bi Q, Weber K 2016 Sol. Energy Mater. Sol. ar Cells 150 32Google Scholar

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    Boccard M, Ding L, Koswatta P, Bertoni M, Holman Z Photovoltaic Specialist Conference pp1-3

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    [54]

    Mews M, Lemaire A, Korte L 2017 IEEE J. Photovoltaics 1

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    Meyer J, Hamwi S, Kröger M, Kowalsky W, Riedl T, Kahn A 2012 Adv. Mater. 24 5408Google Scholar

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    Mcdonnell S, Azcatl A, Addou R, Gong C, Battaglia C, Chuang S, Cho K, Javey A, Wallace R M 2014 ACS Nano 8 6265Google Scholar

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Metrics
  • Abstract views:  11575
  • PDF Downloads:  207
  • Cited By: 0
Publishing process
  • Received Date:  08 November 2018
  • Accepted Date:  06 December 2018
  • Available Online:  01 February 2019
  • Published Online:  20 February 2019

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