Abdul Hasan, Mahmood, Al-Raad, Abbas Abdulameer, Manshd, Abbas Ali, Nadweh, Safwan Mhrez (2025). Circular Bioeconomy Strategies for Organic Waste Valorization: Techno‑Economic and Life‑Cycle Assessment in Al‑Nasiriyah, Iraq. , 14(1), 51-72. doi: 10.48311/ecopersia.2026.104061.0
Mahmood Abdul Hasan; Abbas Abdulameer Al-Raad; Abbas Ali Manshd; Safwan Mhrez Nadweh. "Circular Bioeconomy Strategies for Organic Waste Valorization: Techno‑Economic and Life‑Cycle Assessment in Al‑Nasiriyah, Iraq". , 14, 1, 2025, 51-72. doi: 10.48311/ecopersia.2026.104061.0
Abdul Hasan, Mahmood, Al-Raad, Abbas Abdulameer, Manshd, Abbas Ali, Nadweh, Safwan Mhrez (2025). 'Circular Bioeconomy Strategies for Organic Waste Valorization: Techno‑Economic and Life‑Cycle Assessment in Al‑Nasiriyah, Iraq', , 14(1), pp. 51-72. doi: 10.48311/ecopersia.2026.104061.0
Abdul Hasan, Mahmood, Al-Raad, Abbas Abdulameer, Manshd, Abbas Ali, Nadweh, Safwan Mhrez Circular Bioeconomy Strategies for Organic Waste Valorization: Techno‑Economic and Life‑Cycle Assessment in Al‑Nasiriyah, Iraq. , 2025; 14(1): 51-72. doi: 10.48311/ecopersia.2026.104061.0

Circular Bioeconomy Strategies for Organic Waste Valorization: Techno‑Economic and Life‑Cycle Assessment in Al‑Nasiriyah, Iraq

ECOPERSIA
Volume 14, Issue 1 - Serial Number 55, Autumn 2025, Pages 51-72    PDF (1019.1 K)
Document Type: Original Research
DOI: 10.48311/ecopersia.2026.104061.0
Authors
Mahmood Abdul Hasan1; Abbas Abdulameer Al-Raad2; Abbas Ali Manshd* 2; Safwan Mhrez Nadweh3
1Marshes Research Center, University of Thi-Qar, Iraq
2Directorate of Education Al-Muthanna, Ministry of Education, Iraq
3Department of Computer Engineering, Technical Collage, Imam Ja'afar Al-Sadiq University, Bagdad, Iraq
Abstract
Aims: Most of the over 250,000 t.y⁻¹ of organic municipal waste generated in Al-Nasiriyah is landfilled, which raises the risk of leachate and methane emissions. This study explores sustainable waste valorization strategies through energy recovery and coproduct use.
Materials & Methods: Anaerobic digestion (AD) and hydrothermal carbonization (HTC) were combined to develop and evaluate an integrated pathway. Response-surface and Gompertz models, alongside pilot-scale feedstock characterization, were used to predict hydrochar yields, increased heating values, and methane production under various operating conditions. To assess environmental impacts, such as eutrophication and global warming potential, as well as financial metrics, including net present value (NPV), internal rate of return (IRR), and payback period, a bottom-up techno-economic analysis and a cradle-to-gate life-cycle assessment (ISO 14040/44) were performed.
Findings: Compared to standalone AD, the coupled HTC–AD system reduced greenhouse gas emissions by 67%, generated 6.5 GJ.t⁻¹ of net energy, and demonstrated financial viability with an 18% internal rate of return and a four-year payback period.
Conclusion: The results confirm that the integrated HTC–AD pathway offers a practical, climate-friendly, and sustainable waste-management solution for arid subtropical urban areas like Al-Nasiriyah.
Keywords
Anaerobic digestion; Circular bioeconomy; Hydrothermal carbonization; Life‑cycle assessment (LCA); Techno‑economic analysis (TEA)
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