Waste-to-Energy Innovations and Advances in Hydrothermal Carbonization, Microwave, and Pyrolysis Processes: A Review

Authors

Ali Mohammed Saleh, The Renewable Research Unit, Polytechnic Collage Hawija, Northern Technical University, IraqFollow
Noah Mohammed Saleh, The Renewable Research Unit, Polytechnic Collage Hawija, Northern Technical University, Iraq AND Faculty of Mechanical Engineering University of Tabriz, Iran
Mahmod A. Abdulqader, Oil Products Distribution Company, (OPDC) Salahuldeen Branch, Tikrit, Ministry of Oil, Iraq AND Department of Petroleum Engineering, College of Engineering, Alnoor University, Mosul, Iraq
Hadi Hamdi Mahdi, School of Chemical Engineering University Technology Mara, Shah Alam, Selangor, Malaysia
Jafar Keighobadi, Faculty of Mechanical Engineering University of Tabriz, Iran
Omar K. Ahmed, The Renewable Research Unit, Polytechnic Collage Hawija, Northern Technical University, Iraq
Khalil Farhan Yassin, The Renewable Research Unit, Polytechnic Collage Hawija, Northern Technical University, Iraq
Azil Bahari bin Alias, School of Chemical Engineering University Technology Mara, Shah Alam, Selangor, Malaysia
Omar Abed Habeeb, North Refineries Company Baiji, Ministry of Oil, Iraq
Ibrahim Awad Mohammed, University of Kirkuk Faculty of Education for Pure Sciences Department of Chemistry

Corresponding Author

Ali Mohammed Saleh

Authors ORCID

Mahmod A. Abdulqader: https://orcid.org/0009-0008-1155-0733

Abstract

The accelerating global generation of municipal solid waste, coupled with escalating energy demands, presents one of the most pressing sustainability challenges of the 21st century. Conventional waste disposal pathways, such as landfilling and incineration, exacerbate environmental degradation and resource loss. In response, thermochemical technologies—specifically hydrothermal carbonization (HTC), microwave-assisted processing, and pyrolysis—have emerged as promising strategies for waste valorization and renewable energy recovery. This review critically examines recent advancements in these technologies, emphasizing their roles in converting diverse waste streams into high-value energy carriers and carbon-rich materials. Comparative analysis reveals that HTC operates efficiently under subcritical water conditions, producing hydrochar with tunable physicochemical properties ideal for soil amendment and carbon sequestration. Microwave processing offers rapid, uniform heating with lower energy input and shorter reaction times, enhancing process scalability and efficiency. Pyrolysis, a more established technology, provides high bio-oil and syngas yields suitable for fuel production and chemical synthesis. However, trade-offs in energy balance, process optimization, and emissions management persist. Key findings indicate that hybrid approaches, catalyst innovations, and integration with renewable systems can substantially improve overall energy efficiency and environmental performance. Future research should focus on techno-economic assessments, lifecycle sustainability analyses, and pilot-scale demonstrations to bridge the gap between laboratory success and industrial implementation, advancing the global transition from waste to wealth.

Recommended Citation

Saleh, Ali Mohammed; Saleh, Noah Mohammed; Abdulqader, Mahmod A.; Mahdi, Hadi Hamdi; Keighobadi, Jafar; Ahmed, Omar K.; Yassin, Khalil Farhan; Alias, Azil Bahari bin; Habeeb, Omar Abed; and Mohammed, Ibrahim Awad (2026), Waste-to-Energy Innovations and Advances in Hydrothermal Carbonization, Microwave, and Pyrolysis Processes: A Review, AUIQ Complementary Biological System: Vol. 3: Iss. 1, 84-99.
DOI: https://doi.org/10.70176/3007-973X.1059
Available at: https://acbs.alayen.edu.iq/journal/vol3/iss1/8

Digital Object Identifier (DOI)

10.70176/3007-973X.1059