3066-280XISSN (Online)
Volume 4 , Issue 2 , PP: 13-23, 2025 | Cite this article as | XML | Html | PDF | Full Length Article
Sekar Kidambi Raju 1 *
Doi: https://doi.org/10.54216/MOR.040202
Energy consumption worldwide is increasing due to increased populations, industrialization, and technological development, underlining the importance of efficient energy use. Waste-to-energy technologies are also known as waste-to-energy systems, whereby the production of Energy and Waste Management are considered interrelated. This review summarizes the present trends and state–of–the–art waste management technologies, where renewable energy systems have been integrated into waste management infrastructure and how optimization algorithms help to improve waste management systems. Anaerobic digestion, pyrolysis, and gasification processes raise wastes and convert them into energy products like biogas and syngas, which follow material flow and recovery. Another important area covered in the study is implementing machine learning-optimized methods, genetic algorithms, and artificial neural networks for waste processing and energy recovery. These threats become as follows: high capital costs, feedstock fluctuations, and public perception are tackled alongside solutions like policy support or engagement of the communities involved. This review focuses on the importance of multi-disciplinary systems to achieve future sustainable Waste-to-Energy systems for both the global environment and energy objectives.
Waste Recycling , Energy , Organic resources , Optimization , Recycling , Sustainable environment
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