EFFECT OF PARTICLE SIZE ON MATERIAL RECOVERY AND ELEMENTAL DISTRIBUTION IN THE RECYCLING OF END-OF-LIFE POLYCRYSTALLINE SILICON PHOTOVOLTAIC MODULES

Authors

  • Yasir Albashir Federal University Dutsinma
  • S.M Gumel Department of Industrial Chemistry, Federal University, Dutsinma, P.M.B 5001, Dutsinma, Nigeria.
  • Waheed O. Islamiyat Department of Pure and Industrial Chemistry, Bayero University, P.M.B 3011, Kano, Nigeria.
  • Tahir D. Ibrahim Department of Pure and Industrial Chemistry, Bayero University, P.M.B 3011, Kano, Nigeria.
  • Ndagi Mohammad Department of Pure and Industrial Chemistry, Bayero University, P.M.B 3011, Kano, Nigeria.
  • Sule Erten Ela
  • Hauwa Yahaya Umar Department of Chemistry, College of Education (T), Gombe State, Nigeria.

DOI:

https://doi.org/10.33003/fjs-2026-1007-5088

Keywords:

Photovoltaic Waste, Particle Size Distribution, Recycling, XRD, XRF, Circular Photovoltaics, Material Recovery

Abstract

The rapid deployment of photovoltaic (PV) systems has raised concerns regarding the management of end-of-life (EoL) solar modules. This study investigates the recovery efficiency of polycrystalline silicon PV panels subjected to sequential mechanical and thermal treatments, with emphasis on the influence of particle size distribution on downstream chemical and structural characterization. Disassembled PV modules (≈2 kg per test) were crushed using mortar-and-pestle and hammer-impact methods, followed by sieving into coarse (>5 mm), medium (1–5 mm), and fine (0.08–0.40 mm) fractions. Thermal treatment at 650 °C facilitated the removal of encapsulant materials, after which the recovered fractions were characterized using X-ray diffraction (XRD) and X-ray fluorescence (XRF) analyses. Results indicated improved recovery efficiency in finer fractions, with glass yields increasing from 71.3% in the coarse fraction to 83.4% in the fine fraction. XRD analysis revealed dominant phases of quartz (SiO₂), albite (NaAlSi₃O₈), and lime (CaO), while XRF analysis confirmed enrichment of silicon (Si) and antimony (Sb) in finer fractions. Statistical analysis using one-way ANOVA (p < 0.05) showed significant differences among particle size fractions in terms of recovery yield and elemental composition, indicating the practical importance of particle size optimization in PV recycling processes. The findings demonstrate that particle size engineering plays a critical role in improving material recovery efficiency and supports the development of sustainable circular photovoltaic recycling strategies.

References

1. Wambach K, Libby C, Shaw S, Heath G. Advances in Photovoltaic Module Recycling — IEA-PVPS Task 12 Report. IEA-PVPS; 2024. (IEA-PVPS)

2. Curtis TL, Silverman TJ, et al. Solar Photovoltaic Module Recycling: A Survey of U.S. Policies and Practices. NREL; 2021. (NREL Docs)

3. Preet S., et al. A comprehensive review on the recycling technology of photovoltaic panels. Journal of Cleaner Production. 2024. (ScienceDirect)

4. Wei G., Zhou Y., Hou Z., et al. Review of c-Si PV module recycling and industrial feasibility. EES Solar (review). 2025. (RSC Publishing)

5. Padhamnath P. Recent Progress in the Recovery and Recycling of Polymers from End-of-Life Silicon PV Modules. Sustainability. 2025;17(10):4583. (MDPI)

6. Granata G, Pagnanelli F, Moscardini E, et al. Recycling of photovoltaic panels by physical operations. Solar Energy Materials & Solar Cells. 2014;123:239–248.

7. Latunussa CE, Ardente F, Blengini GA, Mancini L. Life cycle assessment of an innovative recycling process for crystalline silicon PV panels. Solar Energy Materials & Solar Cells. 2016;156:101–111.

8. Dias P, Javimczik S, Benevit M, Veit H. Recycling WEEE: extraction and concentration of silver from waste crystalline silicon photovoltaic modules. Waste Management. 2016;57:220–229.

9. Kang S, Yoo S, Lee J. Experimental investigations for recycling of silicon and glass from waste photovoltaic modules. Renewable Energy. 2012;47:152–159.

10. Yao Y, Zhu J, Zhao J, et al. Hydrometallurgical processes for recycling spent photovoltaic modules: a review. Solar Energy Materials & Solar Cells. 2015;132:36–45.

11. Fiandra V, Bernasconi R, Turetta A, et al. PV module recycling: comparison of technologies and EoL strategies. Renewable Energy. 2020;149:356–365.

12. Lunardi MM, Dias P, Benevit M, Veit HM. Assessment of recycling routes for crystalline silicon PV modules. Waste Management. 2018;75:422–434.

13. Marwede M, Reller A. Future recycling flows of tellurium from cadmium telluride photovoltaic waste. Resources, Conservation and Recycling. 2012;69:35–49.

14. Song J, Liu Y, Zhu H, et al. Thermal treatment of end-of-life photovoltaic modules: experimental investigation and environmental assessment. Journal of Hazardous Materials. 2016;302:379–389.

15. Paiano A. End-of-life of silicon PV panels: Trends in recycling technologies. Journal of Cleaner Production. 2022;359:132078.

16. Kang S, Park J, Kim D, et al. Development of a recycling system for photovoltaic modules. Solar Energy Materials & Solar Cells. 2016;156:1–9.

17. Deng R, Chang N, Ouyang Z, Chong C. Recycling of end-of-life crystalline silicon PV modules: challenges and opportunities. Renewable and Sustainable Energy Reviews. 2019;109:532–550.

18. Heath G, Silverman TJ, Kempe M, et al. Research and development priorities for silicon PV module recycling. Applied Energy. 2020;277:115557.

19. Cucchiella F, D’Adamo I, Rosa P. End-of-life of used photovoltaic modules: a financial and circular-economy analysis. Renewable and Sustainable Energy Reviews. 2015;47:552–561.

20. Tao M, Fthenakis V. Recovery of valuable materials from end-of-life PV modules. Prog Photovolt Res Appl. 2019;27:309–318.

21. Chowdhury MS, Rahman KS, Chowdhury T, et al. An overview of solar photovoltaic panels’ end-of-life material recycling. Energy Strategy Reviews. 2020;27:100431.

22. Frischknecht R, Heath G, Raugei M, et al. Life cycle assessment of future photovoltaic electricity production. Nature Energy. 2020;5:868–880.

23. Raugei M, et al. Economic and environmental assessment of recycling routes for PV modules. Journal of Cleaner Production. 2021.

24. Clemente F, Gagliardi F, et al. Industrial-scale PV recycling: technology readiness and economics. Resources, Conservation & Recycling. 2022;179:106075.

25. Zheng J, Li M, Liu Q. Advances in waste PV module treatment: towards sustainable recycling. Renewable Energy. 2022;192:393–405.

26. Klejnowska K, et al. Recycling of end-of-life PV panels — review of technologies and policy landscape. E3S Web of Conferences. 2024.

27. Marwede M, et al. Industrial recovery flows for CdTe and thin film modules. Resources, Conservation & Recycling.

28. Choi Y, Shin H, Ryu H. Recovery of valuable metals from waste silicon solar modules. Solar Energy Materials & Solar Cells. 2017;162:1–7.

29. Pan P, Benevit M, Veit HM. Photovoltaic solar panels of crystalline silicon: characterization and separation. Waste Management & Research. 2016;34(10):984–992.

30. Paiano A, et al. Techno-economic analysis of PV recycling technologies for glass and metal recovery. Resources Policy. 2021;74:102–115.

31. Nassar NT, Dailey JN, Olivetti EA, et al. Material criticality and supply risks for PV component elements. Nature Materials. 2021;20:1231–1241.

32. Wilkinson C, Gaustad G, Potter W. Antimony in PV glass: supply, recycling risk and processing implications. Glass Technology / Advanced Materials. 2024.

33. Inano H, et al. Impact of silicon and other contaminants on melting and glass recycling from PV panels. Journal of Non-Crystalline Solids. 2025.

34. Pan Pacific Recycling / industry case study coverage (Australia). The Guardian. 2024.

35. Fiandra V, et al. Case studies of modular recycling flows and equipment. Separation and Purification Technology. 2021.

36. Granata G, Pagnanelli F, Moscardini E. Mechanical separation processes for PV recycling: case studies. Separation and Purification Technology. 2021.

37. Dias P, Benevit M, Veit HM. Advances in silver recovery from PV waste. Hydrometallurgy (article). 2020.

38. Raugei M, et al. Life-cycle inventory for PV recycling processes. Energy Policy / J. Cleaner Production. 2020–2022.

39. Kang S, Yoo S, Lee J. (Follow-up experimental recycling studies). Solar Energy Materials & Solar Cells. 2021;221:110864.

40. Shen L, Chen Z, Li N. Critical review on recycling technologies for crystalline silicon PV modules. Journal of Environmental Management. 2021;293:112837.

41. Cheema HA, et al. Global trends and future perspectives in PV recycling: review. Renewable and Sustainable Energy Reviews. 2024.

42. Dias P, Javimczik S, Benevit M, Veit H. Extraction and concentration of Ag from PV modules — pilot data. Waste Management. 2020.

43. Kang S, Park J, Kim D, et al. Design of modular recycling plants for PV modules. Solar Energy Materials & Solar Cells. 2016.

44. Cucchiella F, D’Adamo I, Terzi S. Circular economy of solar photovoltaic panels: an updated review. Renewable and Sustainable Energy Reviews. 2022;158:112152.

45. Deng R, et al. Environmental impacts of crystalline silicon photovoltaic module recycling. Resources, Conservation and Recycling. 2020;159:104854.

46. Fiandra V, Bernasconi R, Turetta A, et al. (additional comparative assessments). Renewable Energy. 2020.

47. McKenna R, et al. Technologies for delamination and polymer recovery from PV modules. Journal of Cleaner Production. 2022.

48. Song J, et al. Thermal delamination processes and emissions. Journal of Hazardous Materials. 2016.

49. Wilk GA, Potter W. Technological trends and new processes for PV waste recycling. Renewable & Sustainable Energy Reviews. 2023.

50. Pan P, et al. Characterization of recycled PV glass for secondary uses. Resources, Conservation & Recycling. 2021.

51. Reller A, Marwede M. Policy drivers and e-waste frameworks for PV recycling. Resources Policy. 2022.

52. Heath G, et al. PV circular economy modeling and scenario analysis. Applied Energy. 2021.

53. Xu L, et al. Antimony material flows and recovery in PV glass recycling context. Journal of Cleaner Production. 2025.

54. NREL. Photovoltaics in the circular economy — web resource & guidance. NREL; 2025.

55. Raugei M, Fthenakis V. Broader resource and climate implications of PV recycling. Nature Energy / Energy Policy. 2020–2022.

56. Clemente F, et al. Techno-economic results from pilot PV recycling lines. Resources, Conservation & Recycling. 2022.

57. Frischknecht R, et al. LCA of future PV electricity and recycling integration. Nature Energy. 2020.

58. Paiano A, et al. Recycling efficiency and glass contamination: industry data. Journal of Cleaner Production. 2022.

59. Kang S, et al. Pilot-scale demonstration of PV recycling flows. Solar Energy Materials & Solar Cells. 2021–2023.

60. Zheng J, Li M, Liu Q. Industrial advances and research directions for PV module recycling. Renewable Energy. 2022.

Fraction Specific Recycling Strategy

Downloads

Published

03-04-2026

Issue

Vol. 10 No. 7 (2026): FUDMA Journal of Sciences - Vol. 10 No. 7

Section

Research Articles

Categories

License

Copyright (c) 2026 Yasir Albashir, S.M Gumel, Waheed O. Islamiyat, Tahir D. Ibrahim, Ndagi Mohammad, Sule Erten Ela, Hauwa Yahaya Umar

Creative Commons License

This work is licensed under a Creative Commons Attribution 4.0 International License.

How to Cite

Albashir, Y., Gumel, S., Islamiyat, W. . O., Ibrahim, T. D., Mohammad, N., Ela, S. E., & Umar, H. Y. (2026). EFFECT OF PARTICLE SIZE ON MATERIAL RECOVERY AND ELEMENTAL DISTRIBUTION IN THE RECYCLING OF END-OF-LIFE POLYCRYSTALLINE SILICON PHOTOVOLTAIC MODULES. FUDMA JOURNAL OF SCIENCES, 10(7), 108-116. https://doi.org/10.33003/fjs-2026-1007-5088