AI Article Synopsis
- The paper explores innovative uses for cotton stalks, focusing on their potential for creating wood composites, producing bioethanol, and generating biogas, while emphasizing the importance of sustainable resource management.
- Environmental assessments reveal that bioethanol production has a smaller carbon footprint and lower climate change impact compared to wood composites and biogas, highlighting its viability as a greener option.
- Findings indicate that while biogas production poses higher human toxicity risks, it contributes less to fossil CO emissions, suggesting a complex balance in evaluating eco-friendly agricultural waste management practices.
Article Abstract
This paper presents a novel approach to utilizing agricultural waste. It compares three different applications for cotton stalks: fabrication of wood composites, bioethanol production, and biogas cradle-to-gate Life cycle assessment production processes. Cotton cultivation generates a lot of debris, mostly cotton stalks, which are incinerated or landfilled, Sustainable resource management is critical for maintaining the ecosystem, and economic stability, and promoting social fairness since it ensures the long-term availability of resources while minimizing environmental damage. The investigation uses the Ecological Footprint, Impact 2002 +, Global Warming Damage Potential, Greenhouse Gas Protocol, Recipe Midpoint, Ecosystem Damage Potential, and CML IA Baseline-open LCA-enabled environmental sustainability assessments. The analysis showed that bioethanol has a lower carbon footprint and climate change impact than both wood composite and biogas production processes, as a result, this could cause a preference for bioethanol production as an environmentally friendly strategy for cotton stalks utilization. While human toxicity was higher in the biogas production process, it emits less fossil CO than biogenic CO. The total climate change of wood composite, bioethanol, and biogas production processes was 0.01761, 0.011300, and 0.01083 points, respectively. This research helps accomplish wider ecological and economic aims by giving insights into sustainable waste management practices.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC10682020 | PMC |
| http://dx.doi.org/10.1038/s41598-023-47817-y | DOI Listing |
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