ENVIRONMENTAL SUSTAINABILITY OF RURAL WASTEWATER-TREATMENT PLANTS VIA LIFE-CYCLE ASSESSMENT WITH EMPHASIS ON CONSTRUCTED WETLANDS

Authors

  • ABDUL WAHED AHMADI Department of Environmental Engineering, İstanbul University-Cerrahpaşa, İstanbul, Türkiye.
  • NILGUN BALKAYA Department of Environmental Engineering, İstanbul University-Cerrahpaşa, İstanbul, Türkiye.

DOI:

https://doi.org/10.55197/qjoest.v6i4.229

Keywords:

wastewater, sustainability, constructed wetland, decommissioning, green initiatives

Abstract

Sustainability plays a pivotal role in environmental engineering and management. Life Cycle Assessment (LCA) serves as a valuable methodology for evaluating the environmental footprint of products, services, or processes throughout their life cycles. LCA offers a quantitative approach and aids in identifying strategies that address environmental challenges rather than merely transferring them. It proves particularly relevant for assessing the sustainability and design of wastewater treatment systems. This study employs the LCA framework to compare various wastewater treatment options suitable for small, decentralized areas. Specifically, the focus lies on evaluating the constructed wetland (CW) within the wastewater treatment (WWT) system across its three main phases: construction, operation, and decommissioning. The investigation examines the impact on diverse environmental categories such as abiotic depletion, global warming, ozone layer depletion, human toxicity, freshwater aquatic ecotoxicity, marine aquatic ecotoxicity, terrestrial ecotoxicity, photochemical oxidation, acidification, and eutrophication, adhering to LCA standards. Findings reveal that natural wastewater treatment methods exhibit lower environmental footprints due to their reduced resource requirements. However, the construction phase of the CW emerges as the primary contributor to most impact categories, accounting for 89% of the overall impact. Notably, marine aquatic ecotoxicity ranks as the most significant impact category, while ozone layer depletion and photochemical oxidation potentials exhibit minimal values.

References

[1] Adhikari, B., Lister, T.E., Reddy, R.G. (2022): Techno-economic and life cycle assessment of aluminum electrorefining from mixed scraps using ionic liquid. – Sustainable Production and Consumption 33: 932-941.

[2] Alam, M.K., Islam, M.A.S., Saeed, T., Rahman, S.M., Majed, N. (2023): Life cycle analysis of lab-scale constructed wetlands for the treatment of industrial wastewater and landfill leachate from municipal solid waste: a comparative assessment. – Water 15(5): 20p.

[3] Alsabri, A., Tahir, F., Al-Ghamdi, S.G. (2021): Life-cycle assessment of polypropylene production in the gulf cooperation council (GCC) region. – Polymers 13(21): 14p.

[4] Braskem Company (2016): I’m green: PE life cycle assessment. – Braskem Company 6p.

[5] Çankaya, S., Pekey, B. (2024): Evaluating the environmental and economic performance of biological and advanced biological wastewater treatment plants by life cycle assessment and life cycle costing. – Environmental Monitoring and Assessment 196(4): 22p.

[6] Chordia, M., Nordelöf, A., Ellingsen, L.A.W. (2021): Environmental life cycle implications of upscaling lithium-ion battery production. – The International Journal of Life Cycle Assessment 26(10): 2024-2039.

[7] Corbella, C., Puigagut, J., Garfí, M. (2017): Life cycle assessment of constructed wetland systems for wastewater treatment coupled with microbial fuel cells. – Science of the Total Environment 584: 355-362.

[8] Corominas, L., Foley, J., Guest, J.S., Hospido, A., Larsen, H.F., Morera, S., Shaw, A. (2013): Life cycle assessment applied to wastewater treatment: state of the art. – Water Research 47(15): 5480-5492.

[9] Dewalkar, S.V., Shastri, S.S. (2021): Environmental impact assessment of wastewater treatment systems: State of the art. – Advance and Innovative Research 8(1): 8p.

[10] Fang, Y.K., Wang, H.C., Fang, P.H., Liang, B., Zheng, K., Sun, Q., Li, X.Q., Zeng, R., Wang, A.J. (2023): Life cycle assessment of integrated bioelectrochemical-constructed wetland system: environmental sustainability and economic feasibility evaluation. – Resources, Conservation and Recycling 189: 10p.

[11] Flores, L., García, J., Pena, R., Garfí, M. (2019): Constructed wetlands for winery wastewater treatment: A comparative Life Cycle Assessment. – Science of the Total Environment 659: 1567-1576.

[12] Gallego-Schmid, A., Tarpani, R.R.Z. (2019): Life cycle assessment of wastewater treatment in developing countries: a review. – Water Research 153: 63-79.

[13] Gmünder, S., Zollinger, M., Dettling, J. (2020): Biogenic Carbon Footprint Calculator for Harvested Wood Products. – World Wide Fund for Nature (WWF) 29p.

[14] Gülçimen, S., Uzal, N. (2022): Comparative Life Cycle Assessment of the Environmental Impacts of Precast Concrete and Brick Walls. – Erciyes Üniversitesi Fen Bilimleri Enstitüsü Fen Bilimleri Dergisi 38(3): 426-433.

[15] Halleux, H., Lassaux, S., Germain, A. (2006): Comparison of life cycle assessment methods, application to a wastewater treatment plant. – In 13th CIRP International Conference on Life Cycvle Engineering, Leuven, Bélgica 4p.

[16] Hydro Aluminium, A.S. (2019): Environmental Product Declaration in accordance with ISO 14025. – The International EPD System 18p.

[17] Issaoui, R. (2023): Sustainable phosphate management: Environmental and Social life cycle assessment of phosphate mining in Tunisia. – KIT Scientific Publishing 254p.

[18] Korre, A., Durucan, S. (2009): Life cycle assessment of aggregates, EVA025–Final report: Aggregates industry life cycle assessment model: Modelling tools and case studies. – Waste and Resources Action Programme, Oxon 10p.

[19] Lakho, F.H., Qureshi, A., Igodt, W., Le, H.Q., Depuydt, V., Rousseau, D.P., Van Hulle, S.W. (2022): Life cycle assessment of two decentralized water treatment systems combining a constructed wetland and a membrane based drinking water production system. – Resources, Conservation and Recycling 178: 15p.

[20] Liu, H., Li, Q., Li, G., Ding, R. (2020): Life cycle assessment of environmental impact of steelmaking process. – Complexity 9p.

[21] Lourenço, N., Nunes, L.M. (2021): Life-cycle assessment of decentralized solutions for wastewater treatment in small communities. – Water Science and Technology 84(8): 1954-1968.

[22] Machado, A.P., Urbano, L., Brito, A.G., Janknecht, P., Salas, J.J., Nogueira, R. (2007): Life cycle assessment of wastewater treatment options for small and decentralized communities. – Water Science and Technology 56(3): 15-22.

[23] Mali, S., Garrett, P. (2022): Life cycle assessment of electricity production from an onshore V150-4.2 MW wind plant. – Vestas 134p.

[24] Marson, A., Manzardo, A., Piron, M., Fedele, A., Scipioni, A. (2021): Life cycle assessment of PVC-A polymer alloy pipes for the impacts reduction in the construction sector. – Chemical Engineering Transactions 86: 721-726.

[25] Montesó Tarrida, A. (2020): Environmental impact assessment of synthetic natural gas of renewable origin from pilot plant. – Universitat Autonoma de Barcelona 28p.

[26] Nunez, P., Jones, S. (2016): Cradle to gate: life cycle impact of primary aluminium production. – The International Journal of Life Cycle Assessment 21(11): 1594-1604.

[27] Olagunju, B.D., Olanrewaju, O.A. (2021): Life cycle assessment of ordinary Portland cement (OPC) using damage oriented (endpoint) approach. – In Proceedings of the International Conference on Industrial Engineering and Operations Management, Singapore 51p.

[28] Onninen, A.S. (2024): Environmental product declaration. – The International EPD System 13p.

[29] Ramsey, D., Ghosh, A., Abbaszadegan, A., Choi, J. (2014): Life cycle assessment of Pre-cast concrete vs. Cast-in-place concrete. – Phoenix, AZ: University of Arizona State, School of Sustainable Engineering and the Build Environment 16p.

[30] Szulc, P., Kasprzak, J., Dymaczewski, Z., Kurczewski, P. (2021): Life cycle assessment of municipal wastewater treatment processes regarding energy production from the sludge line. – Energies 14(2): 29p.

[31] Tabesh, M., Feizee Masooleh, M., Roghani, B., Motevallian, S.S. (2019): Life-cycle assessment (LCA) of wastewater treatment plants: a case study of Tehran, Iran. – International Journal of Civil Engineering 17(7): 1155-1169.

[32] Tarpani, R.R.Z., Azapagic, A. (2023): Life cycle sustainability assessment of advanced treatment techniques for urban wastewater reuse and sewage sludge resource recovery. – Science of The Total Environment 869: 16p.

[33] The European Plastic Pipes and Fittings Association (TEPPFA) (2019): PVC plastic pipe systems vs ductile iron environmental impact comparison. – TEPPFA 4p.

[34] Von Sperling, M. (2007): Wastewater characteristics, treatment and disposal. – IWA publishing 304p.

[35] Zampori, L., Saouter, E., Schau, E., CRISTOBAL, G.J., Castellani, V., Sala, S. (2016): Guide for interpreting life cycle assessment result. – Publications Office of the European Union 60p.

Downloads

Published

2025-12-31

Issue

Vol. 6 No. 4 (2025): QJOEST

Section

Articles

License

Copyright (c) 2025 ABDUL WAHED AHMADI, NILGUN BALKAYA

Creative Commons License

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

How to Cite

ENVIRONMENTAL SUSTAINABILITY OF RURAL WASTEWATER-TREATMENT PLANTS VIA LIFE-CYCLE ASSESSMENT WITH EMPHASIS ON CONSTRUCTED WETLANDS. (2025). Quantum Journal of Engineering, Science and Technology, 6(4), 7-20. https://doi.org/10.55197/qjoest.v6i4.229