Modern Progress in the Advance of High-Efficiency Perovskite (CH3NH3PbI3) Solar Cell using different Hole Transport Layer

Year : 2024 | Volume : | : | Page : –
By

Surendra Yadav,

Ravi Shankar Yadav,

  1. M. Tech Scholar Department of Electronics and Electrical Engineering, Goel Institute of Management and Technology Lucknow Uttar Pradesh India
  2. Assistant Professor Department of Electronics and Electrical Engineering, Goel Institute of Management and Technology Lucknow Uttar Pradesh India

Abstract

One viable alternative for creating new clean energy is solar cells, although they might need additional energy sources. The affordable, easily accessible, and greenhouse gas-free nature of a renewable energy source are its defining characteristics. An alternative that can generate power by converting solar photons into electrical energy is a photovoltaic cell. Over the past 20 years, scientific advancements in photovoltaic technology have presented a number of real-world opportunities that have reduced costs and increased solar cell efficiency. In example, perovskite materials are an interesting chemical family with a broad range of applications in the realm of solar energy. Precisely known for their unique crystal structure and adaptable nature, perovskites have a multitude of remarkable qualities and attributes. When utilizing solar cell simulator software (SCAPS) with perovskite materials like CH3NH3PbI3, the hole transport layer (HTL) is crucial to the efficiency of the solar cells. Using various HTL materials, such as cuprous oxide (Cu2O) and copper thiocyanate (CuSCN), quantitative simulation and modeling have been used to determine the electrical characteristics of the MAPbI3 material used for the active layer for a few parameters, including fill factor (FF), short-circuit current density (Jsc), power conversion rate (PCE), and open-circuit voltage (Voc). The capacitance-frequency (C-F) and capacitance-voltage (C-V) of the previously examined perovskite solar cell have been calculated. The simulated findings demonstrate that the MAPbI3 has specifications for performance such as FF=44.67, PCE=30.83, Voc=2.6041, and Jsc=26.5066 mAcm-2using CuSCN as a HTL and FF=41.63, PCE=30.93, Voc=2.8041, and Jsc=26.5032 mAcm-2using Cu2O as HTL.

Keywords: Perovskite solar cell, CH3NH3PbI3, CuI, C-f, C-V, FF, Voc, Jsc, PCE, CuSCN and Cu2O.

How to cite this article: Surendra Yadav, Ravi Shankar Yadav. Modern Progress in the Advance of High-Efficiency Perovskite (CH3NH3PbI3) Solar Cell using different Hole Transport Layer. Journal of Alternate Energy Sources & Technologies. 2024; ():-.
How to cite this URL: Surendra Yadav, Ravi Shankar Yadav. Modern Progress in the Advance of High-Efficiency Perovskite (CH3NH3PbI3) Solar Cell using different Hole Transport Layer. Journal of Alternate Energy Sources & Technologies. 2024; ():-. Available from: https://journals.stmjournals.com/joaest/article=2024/view=166876

References

  1. W. Chen, S.-Y. Hsiao, C.-Y. Chen, H.-W. Kang, Z.-Y. Huang and H.-W. Lin, “Optical properties of Organometal halide perovskite thin films and general device structure design rules for perovskite single and tandem solar cells,” 3, 9152-9159, 2015.2.
  2. Giordano F, Abate A, Correa Baena J P, Saliba M, Matsui T,Im S H, Zakeeruddin S M, Nazeeruddin M K,Hagfeldt A and Graetzel M, “Enhanced electronic properties in mesoporous TiO2 via lithium doping for high efficiency perovskite solar cells,” 7 10379, 2016.
  3. J. Taghavi, M. Houshmand, M. H. Zandi and N. E. Gorji, “Modeling of optical losses in perovskite solar cells,” 97, 424-428, 2016.4.
  4. Tanuj Tiwari, 2018. “Next generation Soler Power technology”, www.electronicsforu.com, May18,5.
  5. Rashmi Swami, 2012. “Solar Cell,” International Journal of Scientific and Research Publications, Volume 2, Issue 7, July 1 ISSN 2250-3153.6.
  6. Mohammad Tawheed Kibria, Akil Ahammed, Saad Mahmud Sony, Faisal Hossain, Shams-Ul-Islam, “A Review Comparative studies on different generation solar cells technology,” ICEAB, Paper ID E33, 2014.7.
  7. Shruti Sharma, Kamlesh Kumar Jain, Ashutosh Sharma, “Solar cell: In Research and Application –A Review Materials Sciences and Applications,” 2015, 6, 1145-1155.8.
  8. Hosenuzzaman , N.A. Rahim , J. Selvaraj , M. Hasanuzzaman , A.B.M.A. Malek , A. Nahar, “Global prospects, progress, policies, and environmental impact of solar photovoltaic power generation,” Renewable and Sustainable Energy Reviews 41, 284–297, (2015).9.
  9. Kiran ranabhat, Leev patrikeev, Kirill andrianov, Valerii lapshinsky, Elena sofronova “An Introduction to Solar Cell Technology,” 14(2016)4, 405, 481 – 491.10
  10. P. Correa-Baena, A. Abate, M. Saliba, W. Tress, T. J. Jacobsson, M. Grätzel and A. Hagfeldt, “The rapid evolution of highly efficient perovskite solar cells,” Energy Environ. Sci. DOI: 10.1039/C6EE03397K, 2017.11.
  11. Nandi Wu, Yiliang Wu, Daniel Walter, Heping Shen, The Duong, Dale Grant, Chog Barugkin, Xiao Fu, Jun Peng, Thomas White, Kylie Catchpole, and Klaus Weber. “Identifying the Cause of Voltage and Fill Factor Losses in Perovskite Solar Cells by Using Luminescence Measurements,” DOI: 10.1002 /ente201700374.12.
  12. Giordano F, Abate A, Correa Baena J P, Saliba M, Matsui T,Im S H, Zakeeruddin S M, Nazeeruddin M K,Hagfeldt A and Graetzel M, “Enhanced electronic properties in mesoporous TiO2 via lithium doping for high efficiency perovskite solar cells,” 7 10379, 2016.13.
  13. J. Taghavi, M. Houshmand, M. H. Zandi and N. E. Gorji, “Modeling of optical losses in perovskite solar cells,” 97, 424-428, 2016.14.
  14. Tanuj Tiwari, 2018. “Next generation Soler Power technology”, www.electronicsforu.com, May18,15.
  15. Rashmi Swami, 2012. “Solar Cell,” International Journal of Scientific and Research Publications, Volume 2, Issue 7, July 1 ISSN 2250-3153.16.
  16. Mohammad Tawheed Kibria, Akil Ahammed, Saad Mahmud Sony, Faisal Hossain, Shams-Ul-Islam, “A Review Comparative studies on different generation solar cells technology,” ICEAB, Paper ID E33, 2014.17.
  17. Shruti Sharma, Kamlesh Kumar Jain, Ashutosh Sharma, “Solar cell: In Research and Application –A Review Materials Sciences and Applications,” 2015, 6, 1145-1155 .18.
  18. Syed Zulqarnain Haider, Hafeez Anwar, Mingqing Wang, “A comprehensive device modeling of Perovskite solar cell with inorganic copper iodide as hole transport material,” Semicond. Sci. Technol. 33, 0 35001 (12pp), 2018.19.
  19. Verschraegen and M. Burgelman, “Numerical modeling of intra-band tunneling for hetero junction solar cells in SCAPS”, Thin Solid Films, 515 (15), 6276-6279 (2007).
  20. Prasanth kumar and Giri babu, 2016. “Recent advances in perovskite-based solar cells”. Curr. Sci., 111 1173–81.21.
  21. masuko, M. shigematsu, T. hashiguchi, D. fujishima, M. kai, N. yoshimura, T. yamaguchi, Y. ychihashi, T. Yamanishi, T. Takahama, M. Taguchi, E. Maruyama, S. Okamoto, T. Mishima, N. Matsubara, T. Yamanishi, T. Takahama, M. Taguchi, E. Maruyama, and S. Okamoto, “Achievement of More Than 25% Conversion Efficiency with Crystalline Silicon Heterojunction Solar Cell,” IEEE Journal of Photovoltaic Vol.4, Issue6, pp. 1433–1435, 2016.22.
  22. Wehrenfennig, G.E. Eperon, M.B. Johnston, H.J. Snaith, L.M. Herz, 2014. “High Charge Carrier Mobilities and Lifetimes in Organolead Tri halide Perovskite”. Journal of Advanced Materials, Vol. 26 , pp. 1584-1589.23.
  23. Bottaro and Moscowitz, “Current photovoltaic technology: current progress and future prospects,” 1997, MIT-EL77-041W.24.
  24. Homes CC, 2001. “Optical response of high dielectric-constant perovskite related oxide”. science 293 673-625.
  25. Farzad Sadeghi, Mina Neghabi, “Optimization of structure of solar cells based on lead based perovskite via numerical simulation,” Journal of Solar Energy Research 24, 315- 321, 2017.26.
  26. Jeng J-Y, Chiang Y-F, Lee M-H, Pemg S-R, Guo T-F, Chen P and Wen T-C, “CH3NH3PbI3 perovskite/ fullerence planer-hetero junction hybrid solar cells,” 2013, Adv.Mater.25 3727-32.27.
  27. Dazheng Chen and Chunfu Zhang, “Interface Engineering and Electrode Engineering for Organic Solar Cells”,2016, DOI: 10.5772/65312.28.
  28. Pandey and R. Chaujar,“Numerical simulations: Toward the design of 27.6% efficient four-terminal semi-transparent perovskite/SiC  passivated rear contact silicon tandem solar cell,” 2016,100, 656-666.29.
  29. L. Huang, C.-M. Chen, Z.-K. Lin and S.-H. Yang,” Efficiency enhancement of regular-type perovskite solar cells based on Al-doped ZnO nanorods as electron transporting layers,” 2017,102, 94-102.30.
  30. S. Yang, J. H. Noh, N. J. Jeon, Y. C. Kim, S. Ryu, J. Seo and S. I. Seok, “High-performance photovoltaic perovskite layers fabricated through intra molecular exchange,” Science 348, 1234, 2015.31.
  31. Yu Miyazawa, Masashi Ikegami, Hsin-Wei Chen, Takeshi Ohshima, Mitsuru Imaizumi, Kazuyuki Hirose, Tsutomu Miyasaka, “Tolerance of Perovskite Solar Cell to High-Energy Particle Irradiations in Space Environment,” April 27, Miyazawa et al., iScience 2, 148–155, 2018.
Ahead of Print Subscription Original Research
Volume
Received June 28, 2024
Accepted July 4, 2024
Published July 20, 2024
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