REFERENCES

1. Bär, R.; Reinhard, J.; Ehrensperger, A.; Kiteme, B.; Mkunda, T.; Wymann Von Dach, S. The future of charcoal, firewood, and biogas in Kitui County and Kilimanjaro Region: Scenario development for policy support. Energy. Policy. 2021, 150, 112067.

2. Liu, Z.; Luo, W.; Zhang, M.; Zhao, W.; Mostafa, E.; Zhang, Y. Evaluating the potential environmental impact of biomass combustion methods using quantitative universal exergy method. Energ. Environ. Nexus. 2026, 2, e005.

3. Fagarazzi, C.; Miceli, A. New wood chips type for residential use: a pellet substitute for the European market. Renew. Energ. 2026, 261, 125267.

4. Bajwa, D. S.; Peterson, T.; Sharma, N.; Shojaeiarani, J.; Bajwa, S. G. A review of densified solid biomass for energy production. Renew. Sustain. Energ. Rev. 2018, 96, 296-305.

5. Mian, I.; Li, X.; Dacres, O. D.; et al. Combustion kinetics and mechanism of biomass pellet. Energy 2020, 205, 117909.

6. Kumar, B.; Mendoza-martinez, C.; Ferenczi, T.; Nagy, G.; Koós, T.; Szamosi, Z. An experimental study to investigate the impact of solar drying on emission products of woody biomass in the torrefaction process. Energ. Ecol. Environ. 2025, 10, 307-23.

7. Wang, Q.; Liu, K.; Wang, S. Effect of porosity on ignition and burning behavior of cellulose materials. Fuel 2022, 322, 124158.

8. Yan, Y.; Liu, C.; Sun, L.; et al. Biomass pellets prepared via low-temperature precarbonization: Biomass properties with flue gas treatment. J. Anal. Appl. Pyrolysis. 2025, 189, 107118.

9. Wang, S.; Guo, X.; Zhang, X.; Lu, H.; Liu, H. Experimental study on biomass reactive drying based on three major components: cellulose, hemicellulose, and lignin. Chem. Eng. J. 2025, 504, 158675.

10. Zhang, Y.; Zhao, W.; Xie, K.; Li, B. Studies on microwave heating performances of biomass. Energ. Conserv. Technol. 2026, 44, 3-7. Available from: https://link.cnki.net/urlid/23.1302.TK.20260319.1521.002 [accessed on 27 May 2026].

11. Hasan, M.; Baheerathan, B.; Sutradhar, S.; et al. Microwave-assisted synthesis of biomass-derived N-doped carbon dots for metal ion sensing. Carbon. Res. 2025, 4, 49.

12. Zhang, X.; Xu, H.; Xiang, W.; You, X.; Dai, H.; Gao, B. Lignin-impregnated biochar assisted with microwave irradiation for CO2 capture: adsorption performance and mechanism. Biochar 2024, 6, 22.

13. Ke, C.; Li, Y.; Dai, L.; et al. One-pot synthesis of hierarchical ZSM-5 for lifetime improvement in catalytic conversion of plastic waste. Sustain. Carbon. Mater. 2026, 2, e018.

14. Ren, J.; Jiang, J.; Wang, J.; Yuan, X.; Wang, A. Variable frequency microwave induced CO₂ boudouard reaction over biochar. Biochar 2024, 6, 20.

15. Shen, L.; Wang, L.; Zheng, C.; et al. Continuous microwave drying of germinated brown rice: Effects of drying conditions on fissure and color, and modeling of moisture content and stress inside kernel. Drying. Technol. 2020, 39, 669-97.

16. Shen, L.; Zhu, Y.; Wang, L.; Liu, C.; Liu, C.; Zheng, X. Improvement of cooking quality of germinated brown rice attributed to the fissures caused by microwave drying. J. Food. Sci. Technol. 2019, 56, 2737-49.

17. Pedrotti, M. F.; Pereira, L. S.; Bizzi, C. A.; Paniz, J. N.; Barin, J. S.; Flores, E. M. Microwave-induced combustion: thermal and morphological aspects for understanding the mechanism of ignition process for analytical applications. Talanta 2017, 174, 64-71.

18. Hoang, A. T.; Nižetić, S.; Ong, H. C.; et al. Insight into the recent advances of microwave pretreatment technologies for the conversion of lignocellulosic biomass into sustainable biofuel. Chemosphere 2021, 281, 130878.

19. Ma, C.; Hu, J.; Wang, H.; Yu, Y.; Tan, C. Advances and challenges in biomass thermochemical conversion: From resource utilization to process optimization. Renew. Sustain. Energ. Rev. 2026, 226, 116385.

20. Liu, H.; E, J.; Ma, X.; Xie, C. Influence of microwave drying on the combustion characteristics of food waste. Drying. Technol. 2016, 34, 1397-405.

21. Arshanitsa, A.; Akishin, Y.; Zile, E.; Dizhbite, T.; Solodovnik, V.; Telysheva, G. Microwave treatment combined with conventional heating of plant biomass pellets in a rotated reactor as a high rate process for solid biofuel manufacture. Renew. Energ. 2016, 91, 386-96.

22. Chaves, D. H. D. S.; Avila, V. M.; Domingues, L. A. F.; Oliveira, M. M.; Birchal, V. S.; Charbel, A. L. T. Energy and exergy efficiencies analysis of microwave drying of orange pomace biomass. J. Therm. Anal. Calorim. 2023, 148, 13413-25.

23. Gao, H.; Bai, J.; Wei, Y.; et al. Effects of drying pretreatment on microwave pyrolysis characteristics of tobacco stems. Biomass. Conv. Bioref. 2022, 13, 11521-31.

24. Amer, M.; Nour, M.; Ahmed, M.; Ookawara, S.; Nada, S.; Elwardany, A. The effect of microwave drying pretreatment on dry torrefaction of agricultural biomasses. Bioresour. Technol. 2019, 286, 121400.

25. Valdmanis, R.; Zake, M. Selective microwave pretreatment of biomass mixtures for sustainable energy production. Energies 2025, 18, 3677.

26. Li, C.; Li, B.; Gao, G.; et al. Thermal pretreatment of poplar sawdust at 100 °C in water or with microwave heating impacts the pyrolysis behaviors. J. Ind. Eng. Chem. 2023, 125, 189-99.

27. Wang, N.; Liu, K.; Hou, Z.; Zhao, Z.; Li, H.; Gao, X. The comparative techno-economic and life cycle assessment for multi-product biorefinery based on microwave and conventional hydrothermal biomass pretreatment. J. Clean. Prod. 2024, 474, 143562.

28. Li, F.; Li, Y.; Lin, R.; Sun, D.; Zhang, H. A comparative thermodynamic assessment of microwave-assisted and conventional pyrolysis of biomass in poly-generation systems using coupled numerical and process simulations. Energ. Convers. Manage. 2024, 319, 118965.

29. Agu, O. S.; Mupondwa, E.; Tabil, L. G.; Emadi, B.; Li, X. Technoeconomic analysis of microwave torrefaction of biomass with microwave absorber and pelletization. Biomass. Bioenerg. 2026, 206, 108661.

30. Che, Y.; Yan, B.; Li, J.; et al. Microwave applied to the thermochemical conversion of biomass: a review. Renew. Sustain. Energ. Rev. 2025, 216, 115674.

31. Fan, X.; Bian, J.; Li, B.; Xi, Y.; Zi, W. Dielectric response and pyrolysis mechanisms during biomass microwave pyrolysis: intrinsic coupling among heat/mass transfer, microstructural evolution, and microwave energy conversion. Chem. Eng. J. 2026, 527, 171890.

32. Potnuri, R.; Rao, C. S.; Lenka, M.; Sridevi, V.; Basak, T. Microwave-assisted torrefaction of lignocellulosic biomass: a critical review of its role in sustainable energy. Biomass. Bioenerg. 2025, 197, 107777.

33. Lai, Y.; Liu, X.; Davies, M.; et al. Characterisation of wood combustion and emission under varying moisture contents using multiple imaging techniques. Fuel 2024, 373, 132397.

34. Wang, X.; Ma, T.; Sun, J.; et al. Effects of pelletizing pressure and particle size on flame characteristics and potassium release in volatile combustion of biomass pellets. Biomass. Bioenerg. 2025, 199, 107916.

35. Bi̇lgi̇n, S.; Yilmaz, H.; Karayel, D.; Çanakcı, M.; Topakcı, M. Combustion performance and emission characteristics of agricultural residue pellets as alternatives to wood pellets. Energ. Source. Part. A. 2026, 48, 2649946.

36. Holtmeyer, M. L.; Li, G.; Kumfer, B. M.; Li, S.; Axelbaum, R. L. The impact of biomass cofiring on volatile flame length. Energ. Fuel. 2013, 27, 7762-71.

37. Prashanth, P. F.; Gurrala, L.; Mohan, R. V.; Sarvanakumar, K.; Vinu, R. Microwave‐assisted torrefaction and pyrolysis of rice straw pellets for bioenergy. IET. Renewable. Power. Gen. 2022, 16, 2964-77.

38. Goldšteins, L.; Valdmanis, R.; Zaķe, M.; Arshanitsa, A.; Andersone, A. Thermal decomposition and combustion of microwave pre-treated biomass pellets. Processes 2021, 9, 492.

39. Zhang, Y.; Zhang, Y.; Deng, J.; Li, Y.; Shi, X.; Ren, X. Study on the microstructural evolution and spontaneous combustion thermal reaction of coal under photo-thermal synergism. Process. Saf. Environ. Prot. 2025, 196, 106929.

40. Barmina, I.; Goldsteins, L.; Valdmanis, R.; Zake, M. Improvement of biomass gasification/combustion characteristics by microwave pretreatment of biomass pellets. Chem. Eng. Technol. 2021, 44, 2018-25.

41. Feng, L.; Dong, M.; Peng, S.; Wu, M. Non-pyrolysis microwave heating as coal pretreatment for in-situ combustion: reactivity and microstructure. Energ. Source. Part. A. 2023, 45, 2228-39.

42. Fennell, L. P.; Boldor, D. Continuous microwave drying of sweet sorghum bagasse biomass. Biomass. Bioenerg. 2014, 70, 542-52.

43. Yao, L.; Song, Z.; Sun, C.; et al. Study on the evolution of internal and external water of lignite during microwave drying and the moisture reabsorption characteristics of dried lignite. Energ. Source. Part. A. 2020, 47, 3284-301.