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Physical device simulation of dopant-free asymmetric silicon heterojunction solar cell featuring tungsten oxide as a hole-selective layer with ultrathin silicon oxide passivation layer

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  • Mehmood, Haris
  • Nasser, Hisham
  • Zaidi, Syed Muhammad Hassan
  • Tauqeer, Tauseef
  • Turan, Raşit

Abstract

The dopant-related issues are amongst the major performance bottleneck in crystalline silicon solar cells that can be alleviated via implementation of dopant-free layers. This work presents the implementation of tungsten oxide (WOx) and titanium oxide (TiOx) as hole- and electron-selective films for heterostructure solar cell design whereby n-type Si wafer has been passivated with ultrathin silicon oxide (SiO2) layer. Several designs have been investigated including passivated hydrogenated amorphous silicon (i-a-Si:H) and characterized by evaluating work function, electron affinity, interfacial charge, and layer thickness. The high work function of WOx induces significant upward band bending to permit holes transportation towards anode, whereas, low electron-affinity for TiOx reduces the barrier against electrons at the cathode. Smaller band offsets have been observed against minority carriers for devices that employ passivated i-a-Si:H film. However, incorporating SiO2 significantly improves the energy barrier height against minority carriers that leads to an enhancement in electric field along with reduction in recombination. The best-performance device with an optimum SiO2 thickness of 1 nm numerically validated Voc of 751 mV, Jsc 40.2 mA/cm2, FF 79.7%, and η of 24.06%. A comparative analysis with hole-selective vanadium oxide (V2Ox) demonstrated η of 21.73% limited by the low work function of V2Ox.

Suggested Citation

  • Mehmood, Haris & Nasser, Hisham & Zaidi, Syed Muhammad Hassan & Tauqeer, Tauseef & Turan, Raşit, 2022. "Physical device simulation of dopant-free asymmetric silicon heterojunction solar cell featuring tungsten oxide as a hole-selective layer with ultrathin silicon oxide passivation layer," Renewable Energy, Elsevier, vol. 183(C), pages 188-201.
  • Handle: RePEc:eee:renene:v:183:y:2022:i:c:p:188-201
    DOI: 10.1016/j.renene.2021.10.073
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    References listed on IDEAS

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    1. James Bullock & Mark Hettick & Jonas Geissbühler & Alison J. Ong & Thomas Allen & Carolin M. Sutter-Fella & Teresa Chen & Hiroki Ota & Ethan W. Schaler & Stefaan De Wolf & Christophe Ballif & Andrés C, 2016. "Efficient silicon solar cells with dopant-free asymmetric heterocontacts," Nature Energy, Nature, vol. 1(3), pages 1-7, March.
    2. Mehmood, Haris & Nasser, Hisham & Tauqeer, Tauseef & Turan, Raşit, 2019. "Simulation of silicon heterostructure solar cell featuring dopant-free carrier-selective molybdenum oxide and titanium oxide contacts," Renewable Energy, Elsevier, vol. 143(C), pages 359-367.
    3. Kunta Yoshikawa & Hayato Kawasaki & Wataru Yoshida & Toru Irie & Katsunori Konishi & Kunihiro Nakano & Toshihiko Uto & Daisuke Adachi & Masanori Kanematsu & Hisashi Uzu & Kenji Yamamoto, 2017. "Silicon heterojunction solar cell with interdigitated back contacts for a photoconversion efficiency over 26%," Nature Energy, Nature, vol. 2(5), pages 1-8, May.
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    1. Liang, Tao & Chen, Jingyi & Chen, Xiaohang & Su, Shanhe & Chen, Jincan, 2022. "Trade-off between the near-field heat transfer and the space charge effect in graphene-anode thermionic energy converters," Energy, Elsevier, vol. 260(C).

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