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Potential-Induced Performance Degradation (PID) Applied on a Perovskite Solar Cell: Exploring Its Effect on Cell Performance Through Numerical Simulation

Journal of Electronic Materials, ISSN: 1543-186X, Vol: 52, Issue: 5, Page: 3205-3218
2023
  • 17
    Citations
  • 0
    Usage
  • 20
    Captures
  • 1
    Mentions
  • 0
    Social Media
Metric Options:   Counts1 Year3 Year

Metrics Details

  • Citations
    17
  • Captures
    20
  • Mentions
    1
    • News Mentions
      1
      • News
        1

Most Recent News

Recent Research from University of Kebangsaan Highlight Findings in Energy [Potential-induced Performance Degradation (Pid) Applied On a Perovskite Solar Cell: Exploring Its Effect On Cell Performance Through Numerical Simulation]

2023 APR 10 (NewsRx) -- By a News Reporter-Staff News Editor at Energy Daily News -- Fresh data on Energy are presented in a new

Article Description

Metal halide perovskites are regarded as promising photovoltaic candidates in the solar industry due to their high photon-to-current conversion efficiency, outstanding processability, chemical characteristics, and cost-effectiveness. However, their stability is a major concern for large-scale applications. Recently, potential-induced performance degradation (PID) has arisen as a prevalent risk that affects the lifetime of photovoltaics resulting from negative bias and adverse environmental conditions. Throughout this study, the influence of PID on four perovskite (MAPbI, CsPbI, CsGeI, and CsSnI) device structures is demonstrated, and the device performance is evaluated using SCAPS-1D. Intrinsic defects of different scales in the absorber layer are incorporated to trigger the PID effect, and its impact on different PSCs is examined. Additionally, quantum efficiency and impact on band energy are also investigated. The results reveal that the CsPbI-based solar cell has the highest defect tolerance limit of 1 × 10 cm. The study further reveals that under PID, FTO/TiO/CsPbI/NiO/Au shows better stability than other structures, with power conversion efficiency of 18.13%.

Bibliographic Details

Md. Ariful Islam; Md. Akhtaruzzaman; M. Mottakin; Vidhya Selvanathan; Md. Shahiduzzaman; M. N. I. Khan; A. F. M. Masum Rabbani; M. J. Rashid; Mohd Adib Ibrahim; K. Sopian; K. Sobayel

Springer Science and Business Media LLC

Materials Science; Physics and Astronomy; Engineering

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