doi:10.1007/s11705-024-2466-5

PDF(941 KB)

Frontiers of Chemical Science and Engineering ›› 2024, Vol. 18 ›› Issue (10) : 115. DOI: 10.1007/s11705-024-2466-5

Carbon resources to chemicals - RESEARCH ARTICLE

作者信息 +

Experimental study on microwave pyrolysis of eucalyptus camaldulensis leaves: a promising approach for bio-oil recovery

Author information +

History +

Abstract

Eucalyptus species are extensively cultivated trees commonly used for timber production, firewood, paper manufacturing, and essential nutrient extraction, while lacking consumption of the leaves increases soil acidity. The objective of this study was to recover bio-oil through microwave pyrolysis of eucalyptus camaldulensis leaves. The effects of microwave power (450, 550, 650, 750, and 850 W), pyrolysis temperature (500, 550, 600, 650, and 700 °C), and silicon carbide amount (10, 25, 40, 55, and 70 g) on the products yields and bio-oil constituents were investigated. The yields of bio-oil, gas, and residue varied within the ranges of 19.8–39.25, 33.75–46.7, and 26.0–33.5 wt %, respectively. The optimal bio-oil yield of 39.25 wt % was achieved at 650 W, 600 °C, and 40 g. The oxygenated derivatives, aromatic compounds, aliphatic hydrocarbons, and phenols constituted 40.24–74.25, 3.25–23.19, 0.3–9.77, and 1.58–7.75 area % of the bio-oils, respectively. Acetic acid (8.17–38.18 area %) was identified as a major bio-oil constituent, and hydrocarbons with carbon numbers C₁ and C₂ were found to be abundant. The experimental results demonstrate the potential of microwave pyrolysis as an eco-friendly and efficient way for converting eucalyptus waste into valuable bio-oil, contributing to the sustainable utilization of biomass resources.

Keywords

bio-oil recovery / eucalyptus leaves / microwave pyrolysis

引用本文

EndNote

Ris (Procite)

Bibtex

导出引用

. . Frontiers of Chemical Science and Engineering. 2024, 18(10): 115 https://doi.org/10.1007/s11705-024-2466-5

参考文献

原文顺序 | 文献年度倒序 | 文中引用次数倒序

[1]	Ferdan T , Pavlas M , Nevrlý V , Šomplák R , Stehlík P . Greenhouse gas emissions from thermal treatment of non-recyclable municipal waste. Frontiers of Chemical Science and Engineering, 2018, 12(4): 815–831 CrossRef ADS Google scholar
[2]	Wu J , Tang G , Wang R , Yanwei S . Multi-objective optimization for China’s power carbon emission reduction by 2035. Journal of Thermal Science, 2019, 28(2): 184–194 CrossRef ADS Google scholar
[3]	Fang L , Huang T , Lu H , Wu X L , Chen Z , Yang H , Wang S , Tang Z , Li Z , Hu B , Wang X . Biochar-based materials in environmental pollutant elimination, H₂ production and CO₂ capture applications. Biochar, 2023, 5(1): 42 CrossRef ADS Google scholar
[4]	Chen J , Dai L , Mataya D , Cobb K , Chen P , Ruan R . Enhanced sustainable integration of CO₂ utilization and wastewater treatment using microalgae in circular economy concept. Bioresource Technology, 2022, 366: 128188 CrossRef ADS Google scholar
[5]	Pye S , Li F G , Price J , Fais B . Achieving net-zero emissions through the reframing of UK national targets in the post-Paris Agreement era. Nature Energy, 2017, 2(3): 1–7 CrossRef ADS Google scholar
[6]	IEA. Energy Statistics Data Browser, IEA, Paris. Available at IEA website (2022)
[7]	Zhang Y , Wang X . Geographical spatial distribution and productivity dynamic change of eucalyptus plantations in China. Scientific Reports, 2021, 11(1): 19764 CrossRef ADS Google scholar
[8]	Elli E F , Sentelhas P C , Bender F D . Impacts and uncertainties of climate change projections on eucalyptus plantations productivity across Brazil. Forest Ecology and Management, 2020, 474: 118365 CrossRef ADS Google scholar
[9]	Nasir M J , Akhtar W , Oad V K . Spatial distribution of eucalyptus plantation and its impact on the depletion of groundwater resources of tehsil Swat Ranizai, District Malakand. Arabian Journal of Geosciences, 2023, 16(4): 245 CrossRef ADS Google scholar
[10]	Sharma A , Kumar A A , Mohanty B , Sawarkar A N . Critical insights into pyrolysis and co-pyrolysis of poplar and eucalyptus wood sawdust: physico-chemical characterization, kinetic triplets, reaction mechanism, and thermodynamic analysis. Renewable Energy, 2023, 210: 321–334 CrossRef ADS Google scholar
[11]	de Souza Kulmann M S , de Jesus Eufrade-Junior H , Dick G , Schumacher M V , de Azevedo G B , Azevedo G T D O S , Guerra S P S . Belowground biomass harvest influences biomass production, stock, export and nutrient use efficiency of second rotation Eucalyptus plantations. Biomass and Bioenergy, 2022, 161: 106476 CrossRef ADS Google scholar
[12]	Kabir M G , Wang Y , Abuhena M , Azim M F , Al-Rashid J , Rasul N M , Mandal P , Maitra P . Maitra P. A bio-sustainable approach for reducing eucalyptus tree-caused agricultural ecosystem hazards employing Trichoderma bio-sustained spores and mycorrhizal networks. Frontiers in Microbiology, 2023, 13: 1071392 CrossRef ADS Google scholar
[13]	Li M , Yu Z , Bin Y , Huang Z , He H , Zheng A , Ma X . Microwave-assisted pyrolysis of eucalyptus wood with MoO₃ and different nitrogen sources for coproducing nitrogen-rich bio-oil and char. Journal of Analytical and Applied Pyrolysis, 2022, 167: 105666 CrossRef ADS Google scholar
[14]	Yu D , Jin G , Pang Y , Chen Y , Guo S , Shen S . Gas characteristics of pine sawdust catalyzed pyrolysis by additives. Journal of Thermal Science, 2021, 30(1): 333–342 CrossRef ADS Google scholar
[15]	Kosanić T R , Ćeranić M B , Đurić S N , Grković V R , Milotić M M , Brankov S D . Experimental investigation of pyrolysis process of woody biomass mixture. Journal of Thermal Science, 2014, 23(3): 290–296 CrossRef ADS Google scholar
[16]	Leng L , Yang L , Lei X , Zhang W , Ai Z , Yang Z , Zhan H , Yang J , Yuan X , Peng H . . Machine learning predicting and engineering the yield, N content, and specific surface area of biochar derived from pyrolysis of biomass. Biochar, 2022, 4(1): 63 CrossRef ADS Google scholar
[17]	Zhang X , Yang X , Yuan X , Tian S , Wang X , Zhang H , Han L . Effect of pyrolysis temperature on composition, carbon fraction and abiotic stability of straw biochars: correlation and quantitative analysis. Carbon Research, 2022, 1(1): 17 CrossRef ADS Google scholar
[18]	Shiferaw Y , Tedla A , Mellese C , Mengistu A , Debay B , Selamawi Y , Merene E , Awol N . Conversion of coffee residue waste and Eucalyptus globulus leaf extract into an alternative solid fuel. Energy Sources. Part A, Recovery, Utilization, and Environmental Effects, 2018, 40(7): 780–786 CrossRef ADS Google scholar
[19]	Dai L , Wang Y , Liu Y , He C , Ruan R , Yu Z , Jiang L , Zeng Z , Wu Q . A review on selective production of value-added chemicals via catalytic pyrolysis of lignocellulosic biomass. Science of the Total Environment, 2020, 749: 142386 CrossRef ADS Google scholar
[20]	Kundu D , Sharma P , Bhattacharya S , Gupta K , Sengupta S , Shang J . Study of methylene blue dye removal using biochar derived from leaf and stem of Lantana camara L. Carbon Research, 2024, 3(1): 1–14 CrossRef ADS Google scholar
[21]	Zhuang Z , Liu Y , Wei W , Shi J , Jin H . Preparation of biochar adsorption material from walnut shell by supercritical CO₂ pretreatment. Biochar, 2024, 6(1): 1–18 CrossRef ADS Google scholar
[22]	Iglesias S P , Miyazaki M R , Mariano A P , Franco T T . Techno-economic assessment of bio-oil produced from Eucalyptus forestry residues. Industrial Crops and Products, 2021, 171: 113936 CrossRef ADS Google scholar
[23]	Zhang Y , Chen P , Liu S , Peng P , Min M , Cheng Y , Anderson E , Zhou N , Fan L , Liu C . . Effects of feedstock characteristics on microwave-assisted pyrolysis—a review. Bioresource Technology, 2017, 230: 143–151 CrossRef ADS Google scholar
[24]	Allende S , Brodie G , Jacob M V . Breakdown of biomass for energy applications using microwave pyrolysis: a technological review. Environmental Research, 2023, 226: 115619 CrossRef ADS Google scholar
[25]	Shang H , Ye P , Yue Y , Wang T , Zhang W , Omar S , Wang J . Experimental and theoretical study of microwave enhanced catalytic hydrodesulfurization of thiophene in a continuous-flow reactor. Frontiers of Chemical Science and Engineering, 2019, 13(4): 744–758 CrossRef ADS Google scholar
[26]	Zheng A , Xia S , Cao F , Liu S , Yang X , Zhao Z , Tian Y , Li H . Directional valorization of eucalyptus waste into value-added chemicals by a novel two-staged controllable pyrolysis process. Chemical Engineering Journal, 2021, 404: 127045 CrossRef ADS Google scholar
[27]	Omar S , Yang Y , Wang J . A review on catalytic & non-catalytic bio-oil upgrading in supercritical fluids. Frontiers of Chemical Science and Engineering, 2021, 15(1): 4–17 CrossRef ADS Google scholar
[28]	Omar S , Alsamaq S , Yang Y , Wang J . Production of renewable fuels by blending bio-oil with alcohols and upgrading under supercritical conditions. Frontiers of Chemical Science and Engineering, 2019, 13(4): 702–717 CrossRef ADS Google scholar
[29]	Singh R , Singh S , Kumar M . Impact of n-butanol as an additive with eucalyptus biodiesel-diesel blends on the performance and emission parameters of the diesel engine. Fuel, 2022, 277: 118178 CrossRef ADS Google scholar
[30]	Mendoza-Martinez C , Sermyagina E , Saari J , Ramos V F , Vakkilainen E , Cardoso M , Rocha E P A . Fast oxidative pyrolysis of eucalyptus wood residues to replace fossil oil in pulp industry. Energy, 2023, 263: 126076 CrossRef ADS Google scholar
[31]	Xu J , Tahmasebi A , Yu J . An experimental study on the formation of methoxyaromatics during pyrolysis of eucalyptus pulverulenta: yields and mechanisms. Bioresource Technology, 2016, 218: 743–750 CrossRef ADS Google scholar
[32]	Singh R K , Shrivastava D K , Sarkar A , Chakraborty J P . Co-pyrolysis of eucalyptus and sodium polyacrylate: optimization and synergistic effect. Fuel, 2020, 277: 118115 CrossRef ADS Google scholar
[33]	Ramadhan M L , Zarate S , Carrascal J , Osorio A F , Hidalgo J P . Effect of fuel bed size and moisture on the flammability of eucalyptus saligna leaves in cone calorimeter testing. Fire Safety Journal, 2021, 120: 103016 CrossRef ADS Google scholar
[34]	Amutio M , Lopez G , Alvarez J , Olazar M , Bilbao J . Fast pyrolysis of eucalyptus waste in a conical spouted bed reactor. Bioresource Technology, 2015, 194: 225–232 CrossRef ADS Google scholar
[35]	Joubert J E , Carrier M , Dahmen N , Stahl R , Knoetze J H . Inherent process variations between fast pyrolysis technologies: a case study on eucalyptus grandis. Fuel Processing Technology, 2015, 131: 389–395 CrossRef ADS Google scholar
[36]	Kim K H , Kim T S , Lee S M , Choi D , Yeo H , Choi I G , Choi J W . Comparison of physicochemical features of biooils and biochars produced from various woody biomasses by fast pyrolysis. Renewable Energy, 2013, 50: 188–195 CrossRef ADS Google scholar
[37]	Prakash P , Kamble L , Sheeba K N . Experimental studies on biomass pyrolysis using microwave radiation. Energy Sources. Part A, Recovery, Utilization, and Environmental Effects, 2015, 37(24): 2675–2683 CrossRef ADS Google scholar
[38]	Mushtaq F , Abdullah T A T , Mat R , Ani F N . Optimization and characterization of bio-oil produced by microwave assisted pyrolysis of oil palm shell waste biomass with microwave absorber. Bioresource Technology, 2015, 190: 442–450 CrossRef ADS Google scholar
[39]	Venegas-Vásconez D , Arteaga-Pérez L E , Aguayo M G , Romero-Carrillo R , Guerrero V H , Tipanluisa-Sarchi L , Alejandro-Martín S . Analytical pyrolysis of pinus radiata and eucalyptus globulus: effects of microwave pretreatment on pyrolytic vapours composition. Polymers, 2023, 15(18): 3790 CrossRef ADS Google scholar
[40]	Qu T , Guo W , Shen L , Xiao J , Zhao K . Experimental study of biomass pyrolysis based on three major components: hemicellulose, cellulose, and lignin. Industrial & Engineering Chemistry Research, 2011, 50(18): 10424–10433 CrossRef ADS Google scholar
[41]	Heidari A , Stahl R , Younesi H , Rashidi A , Troeger N , Ghoreyshi A A . Effect of process conditions on product yield and composition of fast pyrolysis of eucalyptus grandis in fluidized bed reactor. Journal of Industrial and Engineering Chemistry, 2014, 20(4): 2594–2602 CrossRef ADS Google scholar
[42]	Mourant D , Lievens C , Gunawan R , Wang Y , Hu X , Wu L , Syed-Hassan S S A , Li C Z . Effects of temperature on the yields and properties of bio-oil from the fast pyrolysis of mallee bark. Fuel, 2013, 108: 400–408 CrossRef ADS Google scholar
[43]	Schultz E L , Mullen C A , Boateng A A . Aromatic hydrocarbon production from eucalyptus urophylla pyrolysis over several metal-modified ZSM-5 catalysts. Energy Technology, 2017, 5(1): 196–204 CrossRef ADS Google scholar
[44]	Xu J , Liao Y , Lin Y , Ma X , Yu Z . Study on catalytic pyrolysis of eucalyptus to produce aromatic hydrocarbons by Zn-Fe co-modified HZSM-5 catalysts. Journal of Analytical and Applied Pyrolysis, 2019, 139: 96–103 CrossRef ADS Google scholar
[45]	Gullón B , Gullón P , Lú-Chau T A , Moreira M T , Lema J M , Eibes G . Optimization of solvent extraction of antioxidants from eucalyptus globulus leaves by response surface methodology: characterization and assessment of their bioactive properties. Industrial Crops and Products, 2017, 108: 649–659 CrossRef ADS Google scholar
[46]	Yu Z , Jiang L , Wang Y , Li Y , Ke L , Yang Q , Peng Y , Xu J , Dai L , Wu Q . . Catalytic pyrolysis of woody oil over SiC foam-MCM41 catalyst for aromatic-rich bio-oil production in a dual microwave system. Journal of Cleaner Production, 2020, 255: 120179 CrossRef ADS Google scholar
[47]	Chen C , Tang J , Guo C , Huang H . Effect of composite additives on microwave-assisted pyrolysis of microalgae. Energy Sources. Part A, Recovery, Utilization, and Environmental Effects, 2022, 44(1): 2261–2271 CrossRef ADS Google scholar
[48]	Fan S , Zhang Y , Liu T , Fu W , Li B . Microwave-assisted pyrolysis of polystyrene for aviation oil production. Journal of Analytical and Applied Pyrolysis, 2022, 162: 105425 CrossRef ADS Google scholar
[49]	Hu X , Gunawan R , Mourant D , Wang Y , Lievens C , Chaiwat W , Wu L , Li C Z . Esterification of bio-oil from Mallee (Eucalyptus loxophleba ssp. gratiae) leaves with a solid acid catalyst: conversion of the cyclic ether and terpenoids into hydrocarbons. Bioresource Technology, 2012, 123: 249–255 CrossRef ADS Google scholar
[50]	Le G T , Mala P , Ratchahat S , Charinpanitkul T . Bio-based production of carbon nanotubes via co-pyrolysis of eucalyptus oil and ferrocene. Journal of Analytical and Applied Pyrolysis, 2021, 158: 105257 CrossRef ADS Google scholar

Competing interests

The authors declare that they have no competing interests.

Acknowledgements

We acknowledge the financial support provided by the National Natural Science Foundation of China (Grant No. 52076049), Heilongjiang Province “Double First-class” Discipline Collaborative Innovation Achievement Project (Grant No. LJGXCG2023-080), Heilongjiang Provincial Key R&D Program (Grant No. 2023ZX02C05), and Heilongjiang Provincial Key R&D Program “Unveiling the Leader” Project (Grant No. 2023ZXJ02C04).