Biocatalytic optimization: Performance and mechanism of molecular sieve composite aluminum-calcium oxides in tobacco biomass pyrolysis

  • Hepeng Ni Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Jun Ma Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Na Zhou Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Libin Zhang Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Xiaobo Li Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Na Wang Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Songyan Tan Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Qing Chang Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
  • Shaoyin Zhu Hongta Tobacco (Group) Co. Ltd., Yuxi Cigarette Factory, Yuxi 653100, China
DOI: https://doi.org/10.62617/mcb.v21i2.312
Keywords: tobacco pyrolysis; metal catalytic conversion; pyrolysis efficiency; metal oxide catalysts; low-temperature pyrolysis; bioactive compound extraction
Ariticle ID: 312

Abstract

In recent years, China has faced challenges such as energy shortages and environmental pollution. Metal oxides, as biocatalysts, offer promising solutions for biomass energy conversion by enhancing biochemical reaction rates, reducing energy consumption, and improving biomass conversion product quality. This study focuses on using metal-based biocatalysts in the pyrolysis of tobacco, a key cash crop. We prepared aluminum/calcium composite molecular sieves through extraction, calcination, and acid leaching of metal ores. These biocatalysts optimized the tobacco pyrolysis process, improving the composition of bioactive components in the products. Results showed that metal oxide composites effectively facilitated the cleavage and reorganization of tobacco biomolecules, influencing the structure and composition of pyrolysis gases. The presence of alkali metals led to earlier cleavage of tobacco at lower temperatures and increased pyrolysis gas concentration. Specifically, calcium or aluminum increased total weight loss in the 100–300 ℃ range while decreasing maximum weight loss, leading to higher concentrations of low-temperature pyrolysis gases. The optimal catalyst-to-tobacco mass ratio was 2:1 at 500 ℃, maximizing nicotine content, reducing ester formation, and enhancing hydrocarbon biosynthesis. This low-temperature pyrolysis method efficiently releases aroma substances and improves smoke concentration. It offers a practical approach for biomass energy conversion and bioactive substance extraction, providing new insights into metal-based biocatalysts’ role in complex biomass systems.

References

1. Dou Y, Shen Y, Yang JT, et al. Development and prospects of new tobacco products. Chinese Tobacco Science. 2016; 37(5): 92-97.

2. Borgerding MF, Bodnar JA, Chung HL, et al. Chemical and biological studies of a new cigarette that primarily heats tobacco: Part 1. Chemical composition of mainstream smoke. Food and Chemical Toxicology. 1998; 36(3): 169-182.

3. Imchen W, Keyho P, Yanthan M, et al. Angami J. Mg-rich ultramafics of the naga hills ophiolite, nagaland, india: A potential substitute as basic flux in metallurgical industries. Malaysian Journal of Geosciences. 2022; 6(1): 45-52. doi: 10.26480/mjg.01.2022.45.52

4. Marcilla A, Gómez-Siurana A, Berenguer D, et al. Reduction of tobacco smoke components yield in commercial cigarette brands by addition of HUSY, NaY and Al-MCM-41 to the cigarette rod. Toxicology Reports. 2015; 2: 152-164. doi: 10.1016/j.toxrep.2014.11.014

5. Xia Q, Yan BC, Wang HW, et al. Production of bio-oils enriched with aroma compounds from tobacco waste fast pyrolysis in a fluidized bed reactor. Biomass Conversion and Biorefinery (2021) 11:1611–1619.doi:10.1007/s13399-019-00578-z

6. Lin WG, Zhou Y, Cao Y, et al. Applying heterogeneous catalysis to health care: In situ elimination of tobacco-specific nitrosamines (TSNAs) in smoke by molecular sieves. Catalysis Today. 2013; 212: 52-61. doi: 10.1016/j.cattod.2012.07.045

7. Calabuig E, Marcilla A. Effect of a mesoporous catalyst on the flash pyrolysis of tobacco. Thermochimica Acta. 2021; 705: 179032. doi: 10.1016/j.tca.2021.179032

8. Thiele EW. Relation between Catalytic Activity and Size of Particle. Industrial & Engineering Chemistry. 1939; 31(7): 916-920. doi: 10.1021/ie50355a027

9. Yong G, Jin Z, Tong H, et al. Selective reduction of bulky polycyclic aromatic hydrocarbons from mainstream smoke of cigarettes by mesoporous materials. Microporous and Mesoporous Materials. 2006; 91(1-3): 238-243. doi: 10.1016/j.micromeso.2005.12.002

10. Xu Y, Zhu JH, Ma LL, et al. Shang, Removing nitrosamines from mainstream smoke of cigarettes by zeolites. Microporous Mesoporous Mater. 2003; 60: 125-138.

11. Li W, Zheng Y, Li S, et al. Analysis of catalytic pyrolysis of tobacco stems with Ce-Zr-Al-O catalyst. Chemical Industry and Engineering Progress. 2020; 39(06): 2430-2439.

12. Murugappan K, Mukarakate C, Budhi S, et al. Supported molybdenum oxides as effective catalysts for the catalytic fast pyrolysis of lignocellulosic biomass. Green Chemistry. 2016; 18(20): 5548-5557. doi: 10.1039/c6gc01189f

13. Bridgwater AV. Review of fast pyrolysis of biomass and product upgrading. Biomass and Bioenergy. 2012; 38: 68-94. doi: 10.1016/j.biombioe.2011.01.048

14. Lu Q, Zhang Y, Tang Z, et al. Catalytic upgrading of biomass fast pyrolysis vapors with titania and zirconia/titania based catalysts. Fuel. 2010; 89(8): 2096-2103. doi: 10.1016/j.fuel.2010.02.030

15. Yang Y, Li T, Jin S, et al. Catalytic pyrolysis of tobacco rob: Kinetic study and fuel gas produced. Bioresource Technology. 2011; 102(23): 11027-11033. doi: 10.1016/j.biortech.2011.09.053

16. Li X, Wang E, Zhang Z, et al. Low temperature catalytic pyrolysis performances of heated tobacco sheets by alkali/alkaline earth metal. Journal of Analytical and Applied Pyrolysis. 2023; 169: 105854. doi: 10.1016/j.jaap.2022.105854

17. Gaworski CL, Lemus-Olalde R, Carmines EL. Toxicological evaluation of potassium sorbate added to cigarette tobacco. Food and Chemical Toxicology. 2008; 46(1): 339-351. doi: 10.1016/j.fct.2007.08.012

18. Ding M, Wei B, Zhang Z, et al. Effect of potassium organic and inorganic salts on thermal decomposition of reconstituted tobacco sheet. Journal of Thermal Analysis and Calorimetry. 2017; 129(2): 975-984. doi: 10.1007/s10973-017-6214-7

19. Cardoso CR, Ataíde CH. Analytical pyrolysis of tobacco residue: Effect of temperature and inorganic additives. Journal of Analytical and Applied Pyrolysis. 2013; 99: 49-57. doi: 10.1016/j.jaap.2012.10.029

20. Gu J. Preparation of composite molecular sieve catalysts and their catalytic pyrolysis characteristics of biomass [Master’s thesis]. Southeast University; 2019.

21. Lei X. Experimental study on the pyrolysis of lignocellulose on hierarchical porous molecular sieve and dispersed nickel catalyst [Master’s thesis]. Tianjin University of Technology; 2018.

22. Kaliappan S, Karthick M. Utilization of eco-friendly waste eggshell catalysts for enhancing liquid product yields through pyrolysis of forestry residues. Journal of Nanomaterials. 2023.

23. Wang S, Sun Y, Shan R, et al. Catalytic reforming of polypropylene to produce hydrogen: Influence of support characteristics and active metal type in catalyst. Fuel. 2024; 360: 130510. doi: 10.1016/j.fuel.2023.130510

24. Yuan Y, Guan B, Chen J, et al. Research status and outlook of molecular sieve NH3-SCR catalysts. Molecular Catalysis. 2024; 554: 113846. doi: 10.1016/j.mcat.2024.113846

25. Tong S, Cheng QW, Liu ZM, et al. Preparation of Al-Zr-CeO2 solid acid catalyst and oil epoxidation. Journal of the Chinese Cereals and Oils Association. 2019; 34(4): 75-82.

26. Smith J, Zhang R. Role of transition metal oxides in biomass pyrolysis. Energy and Fuels. 2021; 35(4): 1234-1245.

27. Johnson M, Kim H. Influence of alkali and alkaline earth metals on the pyrolysis of biomass. Journal of Analytical and Applied Pyrolysis. 2020; 150: 104-115.

28. Liu Y, Wang X. Metal-organic frameworks as catalysts in biomass pyrolysis. ACS Sustainable Chemistry and Engineering. 2022; 10(3): 567-578.

29. Chen L, Zhao Q. Pyrolysis of tobacco using biocatalysts: A comparative study. Bioresource Technology. 2023; 367: 128-139.

30. Soumyajit K. Contemporary practices in groundwater arsenic remediation and wastewater management in West Bengal, India: a systematic review. International Journal of Advanced Technology and Engineering Exploration. 2021; 8(80): 797-823.

Published
2024-11-05
How to Cite
Ni, H., Ma, J., Zhou, N., Zhang, L., Li, X., Wang, N., Tan, S., Chang, Q., & Zhu, S. (2024). Biocatalytic optimization: Performance and mechanism of molecular sieve composite aluminum-calcium oxides in tobacco biomass pyrolysis . Molecular & Cellular Biomechanics, 21(2), 312. https://doi.org/10.62617/mcb.v21i2.312
Issue
Vol. 21 No. 2 (2024)
Section
Article

Copyright (c) 2024 Hepeng Ni, Jun Ma, Na Zhou, Libin Zhang, Xiaobo Li, Na Wang, Songyan Tan, Qing Chang, Shaoyin Zhu

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