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Lehmann J, Joseph S. 2024. Biochar for environmental management, 3^rd edition. UK: Routledge. 14 pp doi: 10.4324/9781003297673-1

Kurniawan TA, Othman MHD, Liang X, Goh HH, Gikas P, et al. 2023. Challenges and opportunities for biochar to promote circular economy and carbon neutrality. Journal of Environmental Management 332:117429

Liang PC, Chen WH. 2025. Present and future prospects of biochar. ACS Sustainable Resource Management 2:684−686

Bora RR, Tao Y, Lehmann J, Tester JW, Richardson RE, et al. 2020. Techno-economic feasibility and spatial analysis of thermochemical conversion pathways for regional poultry waste valorization. ACS Sustainable Chemistry & Engineering 8:5763−5775

Syed S, Acquaye A, Khalfan MM, Obuobisa-Darko T, Yamoah FA. 2024. Decoding sustainable consumption behavior: a systematic review of theories and models and provision of a guidance framework. Resources, Conservation & Recycling Advances 23:200232

Biederman LA, Harpole WS. 2013. Biochar and its effects on plant productivity and nutrient cycling: a meta-analysis. GCB Bioenergy 5:202−214

Rababah MM, Al-Oqla FM, Wasif M. 2022. Application of analytical hierarchy process for the determination of green polymeric-based composite manufacturing process. International Journal on Interactive Design and Manufacturing (IJIDeM) 16:943−954

Deng X, Teng F, Zhang X, Fan JL, Forsell N, et al. 2025. Co-deploying biochar and bioenergy with carbon capture and storage improves cost-effectiveness and sustainability of China's carbon neutrality. One Earth 8:101172

Amalina F, Krishnan S, Zularisam A, Nasrullah M. 2025. An extensive analysis and environmental sustainability applications of multifunctional biochar developments: current trends and technological advances. Green Technologies and Sustainability 3:100174

Awasthi MK. 2022. Engineered biochar: a multifunctional material for energy and environment. Environmental Pollution 298:118831

Gupta S, Kua HW. 2017. Factors determining the potential of biochar as a carbon capturing and sequestering construction material: critical review. Journal of Materials in Civil Engineering 29:04017086

Inayat A, Ahmed A, Tariq R, Waris A, Jamil F, et al. 2021. Techno-economical evaluation of bio-oil production via biomass fast pyrolysis process: a review. Frontiers in Energy Research 9:770355

Sudarsan JS, Goel M, Jahangiri H, Rout PR, Tavakolian M, et al. 2025. Sustainable food waste management: a critical review on biochar production and applications. Sustainable Food Technology 3:1723−1743

Parthasarathy P, Alherbawi M, Shahbaz M, Mackey HR, McKay G, et al. 2024. Conversion of oil palm waste into value-added products through pyrolysis: a sensitivity and techno-economic investigation. Biomass Conversion and Biorefinery 14:9667−9687

Atukunda A, Ibrahim MG, Fujii M, Ookawara S, Nasr M. 2024. Dual biogas/biochar production from anaerobic co-digestion of petrochemical and domestic wastewater: a techno-economic and sustainable approach. Biomass Conversion and Biorefinery 14:8793−8803

Janiszewska-Latterini D, Ortigueira J, Lopes TF, Gościańska-Łowińska J, Augustyniak-Wysocka D, et al. 2025. Social awareness as a catalyst for biochar adoption in the agricultural and forestry sectors. Global Change Biology Bioenergy 17:e70077

Gupta J, Bai X, Liverman DM, Rockström J, Qin D, et al. 2024. A just world on a safe planet: a Lancet Planetary Health–Earth Commission report on Earth-system boundaries, translations, and transformations. The Lancet Planetary Health 8:e813−e873

Kirchherr J, Reike D, Hekkert M. 2017. Conceptualizing the circular economy: an analysis of 114 definitions. Resources, Conservation and Recycling 127:221−232

Raja KS, Maliha A, Paul S, Shakur MS, Bari AM. 2025. Unraveling the obstacles to transform agro-wastes into value-added bioproducts: implications for sustainability. Sustainable Operations and Computers 6:171−188