THERMAL SCIENCE

International Scientific Journal

External Links

STUDY ON PID PERFORMANCE DEGRADATION BASED ON PASSIVATION MATERIALS SUCH AS ALUMINA/SILICON NITRIDE SIN CRYSTALLINE SILICON SOLAR CELLS

ABSTRACT
Solar energy is a pure and reproducible energy. China has paid more and more consideration to the investigation and employment of solar energy. The investigation focuses on the phenomenon of PID capability degradation of inactivation mediums for instance alumina/silicon nitride in transparent silicon high-efficiency solar cells. Through the laboratorial investigation on the effect of individual in-activation membrane processes on the PID damping behavior, it is found that the deposition approach of silicon oxide and silicon nitride inactivation membranes on the surface of transparent silicon cells directly affects the PID damping. Excellent anti-PID capability; single-layer silicon oxide membrane with the same thickness has better anti-PID capability than silicon nitride membrane. Double-layer silicon oxide/silicon nitride superimposed membrane with the enhancement of refractive index, the anti-PID damping capability gradually enhancements, and better anti-PID capability than monolayer silicon nitride. Investigation on the PID capability damping of inactivation mediums is of great significance to further the capability of solar cells and help to further the effective employment of solar energy.
KEYWORDS
PAPER SUBMITTED: 2022-10-22
PAPER REVISED: 2022-11-15
PAPER ACCEPTED: 2022-12-12
PUBLISHED ONLINE: 2023-01-07
DOI REFERENCE: https://doi.org/10.2298/TSCI221022222G
CITATION EXPORT: view in browser or download as text file
THERMAL SCIENCE YEAR 2023, VOLUME 27, ISSUE Issue 1, PAGES [375 - 387]
REFERENCES
  1. G Li, Y Lu, Q Xuan, G Pei, X Zhao. Corrections to "Corrosion-Induced AC Impedance Elevation in Front Electrodes of Crystalline Silicon Photovoltaic Cells Within Field-Aged Photovoltaic Modules". IEEE Journal of Photovoltaics, 2019, 9(4):1154-1154.
  2. Daqing Yang; Haiduo Liang; Yujie Liu; Man Hou; Liping Kan; Yijia Yang; Zijian Zang. Large rea Luminescent Downshifting Layer containing Eu3+ Complex for Crystalline Silicon Solar Cells. Dalton Transactions, 2020, 49(15):4725-4731.
  3. Jonai S, Tanaka A, Muramatsu K, et al. Effect of additives in electrode paste of p-type crystalline Si solar cells on potential-induced degradation. Solar Energy, 2019, 188(AUG.):1292-1297.
  4. A Ahmad, Y Jin, C Zhu, I Javed, MW Akram. Photovoltaic cell defect classification using convolutional neural network and support vector machine. IET Renewable Power Generation, 2020, 14(14):2693-2702.
  5. Niyaz H M, Meena R, Gupta R. Impact of cracks on crystalline silicon photovoltaic modules temperature distribution. Solar Energy, 2021, 225(11-12):148-161.
  6. Bouaichi A, Merrouni A A, Amrani A E, et al. Long-term experiment on p-type crystalline PV module with potential induced degradation: Impact on power performance and evaluation of recovery mode. Renewable Energy, 2022, 183(C):472-479.
  7. Arfin T, Arshiya Tarannum K. Review on detection of phenol in water. Advanced Materials Letters, 2019, 10(11): 753-785.
  8. Liang S X, Xi X C, Li Y R. Study of the remediation effects of passivation materials on Pb-contaminated soil. Open Chemistry, 2020, 18(1):911-917.
  9. Mishra S, Bhargava K, Deb D. Numerical simulation of potential induced degradation (PID) in different thin-film solar cells using SCAPS-1D. Solar Energy, 2019, 188(AUG.):353-360.
  10. P Kivík, Baca P, Kazelle J. Measurement of Impedance of AGM Solar Battery for RAPS Applications. ECS Transactions, 2021, 105(1):151-158.
  11. Shubhra S, Singh B. Three-Phase Grid-Interactive Solar PV-Battery Microgrid Control Based on Normalized Gradient Adaptive Regularization Factor Neural Filter. IEEE Transactions on Industrial Informatics, 2020, 16(4):2301-2314.
  12. Salim H K, Stewart R A, Sahin O. Drivers, barriers and enablers to end-of-life management of solar photovoltaic and battery energy storage systems: A systematic literature review. Journal of Cleaner Production, 2019, 211(FEB.20):537-554.
  13. F Zare, G Najafi, P Ghiasi, E Fayyazi, T Yusaf, M Mazlan. Applying Solar Energy in the Combination of Solar Dryer with Olive Harvesting Machine to Reduce Energy Losses. Sustainability, 2022, 14(3):3751-3779.
  14. AE Cagle, A Armstrong, G Exley, SM Grodsky, J Macknick, J Sherwin, RR Hernandez. The Land Sparing, Water Surface Use Efficiency, and Water Surface Transformation of Floating Photovoltaic Solar Energy Installations. Sustainability, 2020, 12(19):8154-8175.
  15. Y Noorollahi, M Mohammadi, H Yousefi, A Anvari-Moghaddam. A Spatial-Based Integration Model for Regional Scale Solar Energy Technical Potential. Sustainability, 2020, 12(5):1890-1908.
  16. Singh B, Knueven B. Lagrangian relaxation-based heuristics for a chance-constrained optimization model of a hybrid solar-battery storage system. Journal of Global Optimization, 2021, 80(4):965-989.
  17. Chandran V P, Kewat S, Singh B. Multi-Objective Control and Operation of Grid Connected Small Hydro-Solar PV-Battery Energy Storage Based Distributed Generation. IET Renewable Power Generation, 2020, 14(16):3259-3272.
  18. Sun Z, He Y, Xiong B, et al. Performance‐enhancing approaches for PEDOT: PSS‐Si hybrid solar cells. Angewandte Chemie International Edition, 2021, 60(10): 5036-5055.
  19. Ye J, Byranvand M M, Martínez C O, et al. Defect passivation in lead‐halide perovskite nanocrystals and thin films: toward efficient LEDs and solar cells. Angewandte Chemie, 2021, 133(40): 21804-21828.
  20. Li Y, Wu J. Optimum Integration of Solar Energy with Battery Energy Storage Systems. IEEE Transactions on Engineering Management, 2020, 69(3):697-707.

© 2024 Society of Thermal Engineers of Serbia. Published by the Vinča Institute of Nuclear Sciences, National Institute of the Republic of Serbia, Belgrade, Serbia. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution-NonCommercial-NoDerivs 4.0 International licence