Journal of Guangdong University of Technology ›› 2022, Vol. 39 ›› Issue (01): 14-20,62.doi: 10.12052/gdutxb.210118

Previous Articles     Next Articles

Research Progress of Multifunctional Lignin-based Materials

Ma Ming-guo, Yuan Qi   

  1. College of Materials Science and Technology, Beijing Forestry University, Beijing 100083, China
  • Received:2021-08-10 Online:2022-01-25 Published:2022-01-20

HTML

PDF (PC)

3189

Abstract: Lignin has a wide range of sources, low price, and complex structure. It is a renewable phenolic polymer in nature. It can be transformed into energy, chemicals, and functional materials, and has a potential application prospect. The research progress of multifunctional lignin materials is reviewed, especially based on typical examples, and the progress of lignin in the fields of energy, environment, sensing and carbon peak and carbon neutralization discussed. Finally, the problems and potential development direction of multifunctional lignin materials are proposed based on our knowledge. Solutions and theoretical support are provided for the applications of multifunctional lignin-based materials.

Key words: lignin, functional materials, energy, emission peak and carbon neutrality

CLC Number: 

  • S216.3
[1] RALPH J, LAPIERRE C, BOERJAN W. Lignin structure and its engineering [J]. Current Opinion in Biotechnology, 2019, 56: 240-249.
[2] YANG H T, YU B, XU X D, et al. Lignin-derived bio-based flame retardants toward high-performance sustainable polymeric materials [J]. Green Chemistry, 2020, 22: 2129-2161.
[3] LIU C, WU S L, ZHANG H Y, et al. Catalytic oxidation of lignin to valuable biomass-based platform chemicals: a review [J]. Fuel Processing Technology, 2019, 191: 181-201.
[4] LI S M, SUN S L, MA M G, et al. Lignin-based carbon/CePO4 nanocomposites: solvothermal fabrication, characterization, thermal stability, and luminescence [J]. Bioresources, 2013, 8: 4155-4170.
[5] LI S X, LI M F, BING J, WU X F, et al. Preparation of organic acid lignin submicrometer particle as a natural broad-spectrum photo-protection agent [J]. International Journal of Biological Macromolecules, 2019, 132: 836-843.
[6] LIU R, DAI L, XU C L, et al. Lignin-based micro- and nanomaterials and their composites in biomedical applications [J]. ChemSusChem, 2020, 13: 4266-4283.
[7] WANG H L, PU Y Q, RAGAUSKAS A, et al. From lignin to valuable products-strategies, challenges, and prospects [J]. Bioresource Technology, 2019, 271: 449-461.
[8] PONNUSAMY V K, NGUYEN D D, DHARMARAJA J, et al. A review on lignin structure, pretreatments, fermentation reactions and biorefinery potential [J]. Bioresource Technology, 2019, 271: 462-472.
[9] 宋国勇. “木质素优先”策略下林木生物质组分催化分离与转化研究进展[J]. 林业工程学报, 2019, 4(5): 1-10.
SONG G Y. The development of catalytic fractionation and conversion of lignocellulosic biomass under lignin-first strategy [J]. Journal of Forestry Engineering, 2019, 4(5): 1-10.
[10] DENG J, SUN S F, ZHU E Q, et al. Sub-micro and nano-lignin materials: small size and rapid progress [J]. Industrial Crops & Products, 2021, 164: 113412.
[11] SHI Z J, MA M G. Synthesis, structure, and applications of lignin-based carbon materials: a review [J]. Science of Advanced Materials, 2019, 11: 18-32.
[12] MA C, KIM T H, LIU K, et al. Multifunctional lignin-based composite materials for emerging applications [J]. Frontiers in Bioengineering and Biotechnology, 2021, 9: 708976.
[13] 陈小红. Rh(Ⅲ)催化含氮有机物与重氮化合物的偶联反应 [D]. 北京: 北京林业大学, 2018.
[14] 孙建奎. 基于木质素优先的催化解聚及生物质全组分分级转化[D]. 北京: 北京林业大学, 2019.
[15] 李赫龙. 后过渡金属催化木质素氢解路线及机理研究[D]. 北京: 北京林业大学, 2020.
[16] 陈雪. 速生生物质半纤维素及木质素组分转化为化学品研究[D]. 北京: 北京林业大学, 2020.
[17] 毛健贞. 乌拉草木质素结构解析及预处理过程中的木质素结构变化[D]. 北京: 北京林业大学, 2014.
[18] RENCORET J, PRINSEN P, GUTIERREZ A, et al. Isolation and structural characterization of the milled wood lignin, dioxane lignin, and cellulolytic lignin preparations from brewer's spent grain [J]. Journal of Agricultural and Food Chemistry, 2015, 63: 603-613.
[19] ANDO D, NAKATSUBO T, TAKANO T, et al. Multi-step degradation method for beta-O-4 linkages in lignins: gamma-TTSA method. Part 3. Degradation of milled wood lignin (MWL) from Eucalyptus globulus [J]. Holzforschung, 2013, 67: 835-841.
[20] JUNG H G, MERTENS D R, PAYNE, A J. Correlation of acid detergent lignin and Klason lignin with digestibility of forage dry matter and neutral detergent fiber [J]. Journal of Dairy Science, 1997, 80: 1622-1628.
[21] YE Q Q, YOKOYAMA T. Revisiting the mechanism of beta-O-4 bond cleavage during acidolysis of lignin VII: acidolyses of non-phenolic C-6-C-2-type model compounds using HBr, HCl and H2SO4, and a proposal on the characteristic action of Br- and Cl- [J]. Journal of Wood Science, 2020, 66: 80.
[22] GUERRA A, FILPPONEN I, LUCIA L A, et al. Toward a better understanding of the lignin isolation process from wood [J]. Journal of Agricultural and Food Chemistry, 2006, 54: 5939-5947.
[23] LIAO J J, ABD LATIF N H, TRACHE D, et al. Current advancement on the isolation, characterization and application of lignin [J]. International Journal of Biological Macromolecules, 2020, 162: 985-1024.
[24] COLOMBO S M, ZHANG Z, WONG D F, et al. Hydrolysis lignin as a multifunctional additive in Atlantic salmon feed improves fish growth performance and pellet quality and shifts gut microbiome [J]. Aquaculture Nutrition, 2020, 26: 1353-1368.
[25] 李立霞. 多级孔分子筛负载铜基催化剂的制备及其催化木质素选择性氧化解聚[D]. 广州: 华南理工大学, 2020.
[26] 李章敏. 金属基离子液体定向解聚木质素制备高值化学品的研究[D]. 广州: 华南理工大学, 2018.
[27] 邵鲁鹏. 工业木质素热化学转化制备芳香化学品的研究[D]. 北京: 北京林业大学, 2018.
[28] 高士帅. 木质素衍生物改性脲醛树脂的机制及其性能研究[D]. 北京: 北京林业大学, 2020.
[29] 蔡诚. pH响应木质素表面活性剂的合成及其在木质纤维素酶解和酶回收中的应用[D]. 广州: 华南理工大学, 2020.
[30] 秦延林. 羟丙基磺化碱木质素染料分散剂及草酸预处理制备纳米纤维素的研究[D]. 广州: 华南理工大学, 2016.
[31] 武颖. 木质素天然高分子紫外防护剂的广谱化改性及微结构调控[D]. 广州: 华南理工大学, 2020.
[32] 李涛. 木质素基多功能缓控释肥料的制备及其性能研究[D]. 兰州: 兰州大学, 2019.
[33] 贺晓艳. 改性纳米木质素增强可降解聚合物薄膜性能研究[D]. 哈尔滨: 东北林业大学, 2019.
[34] ZHU J D, YAN C Y, ZHANG X, et al. A sustainable platform of lignin: from bioresources to materials and their applications in rechargeable batteries and supercapacitors [J]. Progress in Energy and Combustion Science, 2020, 76: 100788.
[35] PARK J H, RANA H H, LEE J Y, et al. Renewable flexible supercapacitors based on all-lignin-based hydrogel electrolytes and nanofiber electrodes [J]. Journal of Materials Chemistry A, 2019, 7: 16962-16968.
[36] LIU S, MA M G. Lignin-derived nitrogen-doped polyacrylonitrile/polyaniline carbon nanofibers by electrospun method for energy storage [J]. Ionics, 2020, 26(9): 4651-4660.
[37] FU F B, YANG D J, ZHANG W L, et al. Green self-assembly synthesis of porous lignin-derived carbon quasi-nanosheets for high-performance supercapacitors [J]. Chemical Engineering Journal, 2020, 392: 123721.
[38] JHA S, MEHTA S, CHEN Y, et al. Design and synthesis of lignin-based flexible supercapacitors [J]. ACS Sustainable Chemistry & Engineering, 2020, 8: 498-511.
[39] HEROU S, BAILEY J J, KOK M, et al. High-density lignin-derived carbon nanofiber supercapacitors with enhanced volumetric energy density [J]. Advanced Science, 2021: 2100016.
[40] LIU H Y, XU T, LIU K, et al. Lignin-based electrodes for energy storage application [J]. Industrial Crops & Products, 2021, 165: 113425.
[41] SUN Y C, WANG T T, SUN X Y, et al. The potential of biochar and lignin-based adsorbents for wastewater treatment: Comparison, mechanism, and application? a review [J]. Industrial Crops and Products, 2021, 166: 113473.
[42] SUPANCHAIYAMAT N, JETSRISUPARB K, KNIJNENBURG J T N, et al. Lignin materials for adsorption: current trend, perspectives and opportunities [J]. Bioresource Technology, 2019, 272: 570-581.
[43] LI Y L, WU M, WANG B, et al. Synthesis of magnetic lignin-based hollow microspheres: a highly adsorptive and reusable adsorbent derived from renewable resources [J]. ACS Sustainable Chemistry & Engineering, 2016, 4: 5523-5532.
[44] MA Y Z, ZHENG D F, MO Z Y, et al. Magnetic lignin-based carbon nanoparticles and the adsorption for removal of methyl orange [J]. Colloids and Surfaces A, 2018, 559: 226-234.
[45] JIANG X Y, WANG G H, LIU Q J, et al. Graft copolymerization of acrylic acid on Kraft lignin to enhance aniline adsorption from aqueous solution [J]. TAPPI Journal, 2019, 18: 75-84.
[46] DAI L, LI Y T, LIU R, et al. Green mussel-inspired lignin magnetic nanoparticles with high adsorptive capacity and environmental friendliness for chromium (III) removal [J]. International Journal of Biological Macromolecules, 2019, 132: 478-486.
[47] SUI W J, PANG T R, WANG G H, et al. Stepwise ethanol-water fractionation of enzymatic hydrolysis lignin to improve its performance as a cationic dye adsorbent [J]. Molecules, 2020, 25: 2603.
[48] MENG L Y, MA M G, JI X X. Preparation of lignin-based carbon materials and its application as a sorbent [J]. Materials, 2019, 12: 1111.
[49] AN L, SI C L, BAE J H, et al. One-step silanization and amination of lignin and its adsorption of Congo red and Cu(II) ions in aqueous solution [J]. International Journal of Biological Macromolecules, 2020, 159: 222-230.
[50] CHOKKAREDDY R, REDHI G G, KARTHICK T. A lignin polymer nanocomposite based electrochemical sensor for the sensitive detection of chlorogenic acid in coffee samples [J]. Heliyon, 2019, 5: e01457.
[51] YUN X J, ZHANG Q T, LUO B, et al. Fabricating flexibly resistive humidity sensors with ultra-high sensitivity using carbonized lignin and sodium alginate [J]. Electroanalysis, 2020, 32: 2282-2289.
[52] WANG Q H, PAN X F, LIN C M, et al. Biocompatible, self-wrinkled, antifreezing and stretchable hydrogel-based wearable sensor with PEDOT: sulfonated lignin as conductive materials [J]. Chemical Engineering Journal, 2019, 370: 1039-1047.
[53] WANG Q H, PAN X F, GUO J J, et al. Lignin and cellulose derivatives-induced hydrogel with asymmetrical adhesion, strength, and electriferous properties for wearable bioelectrodes and self-powered sensors [J]. Chemical Engineering Journal, 2021, 414: 128903.
[54] WANG Q H, LAN J X, HUA Z F, et al. An oriented Fe3+-regulated lignin-based hydrogel with desired softness, conductivity, stretchability, and asymmetric adhesiveness towards anti-interference pressure sensors [J]. International Journal of Biological Macromolecules, 2021, 184: 282-288.
[55] HAN X, LV Z L, RAN F L, et al. Green and stable piezoresistive pressure sensor based on lignin-silver hybrid nanoparticles/polyvinyl alcohol hydrogel [J]. International Journal of Biological Macromolecules, 2021, 176: 78-86.
[56] WANG F, GAO C H, ZHANG W L, et al. Industrial structure optimization and low-carbon transformation of Chinese industry based on the forcing mechanism of CO2 emission peak target [J]. Sustainability, 2021, 13: 4417.
[57] NWACHUKWU C M, WANG C, WETTERLUND E. Exploring the role of forest biomass in abating fossil CO2 emissions in the iron and steel industry—the case of Sweden [J]. Applied Energy, 2021, 288: 116558.
[58] QUACOE D, WEN X Z, QUACOE D. Nexus among biomass consumption, economic growth, and CO2 emission based on the moderating role of biotechnology: evidence from China [J]. Environmental Science and Pollution Research, 2021, 28: 15755-15767.
[59] BAUER N, KLEIN D, HUMPENODER F, et al. Bio-energy and CO2 emission reductions: an integrated land-use and energy sector perspective [J]. Climatic Change, 2020, 163: 1675-1693.
[60] SULAIMAN C, ABDUL-RAHIM A S. Can clean biomass energy use lower CO2 emissions in African economies? empirical evidence from dynamic long-run panel framework [J]. Environmental Science and Pollution Research, 2020, 27: 37699-37708.
[61] DESSBESELL L, PALEOLOGOU M, LEITCH M, et al. Global lignin supply overview and Kraft lignin potential as an alternative for petroleum-based polymers [J]. Renewable & Sustainable Energy Reviews, 2020, 123: 109768.
[62] LI D Z, HUANG G Y, ZHU S Y, et al. How to peak carbon emissions of provincial construction industry? scenario analysis of Jiangsu Province [J]. Renewable & Sustainable Energy Reviews, 2021, 144: 110953.
[1] Fu Zheng-xin, Liu Shuang, Duan Yi-qiang, Zhu Wei-dong. A Coordinated Framework for Power Demand Response Resources Participating in Gas Market [J]. Journal of Guangdong University of Technology, 2023, 40(02): 64-73.
[2] Yuan Jun, Zhang Yun, Zhang Gui-dong, Li Zhong, Chen Zhe, Yu Sheng-long. A Survey of Energy Management System Based on Adaptive Dynamic Programming [J]. Journal of Guangdong University of Technology, 2022, 39(05): 21-28.
[3] Wang Feng, Li Yu-long, Lin Zhi-fei, Cui Miao, Zhang Guang-chi. An Online Resource Allocation Design for Computation Capacity Maximization in Energy Harvesting Mobile Edge Computing Systems [J]. Journal of Guangdong University of Technology, 2022, 39(04): 17-23.
[4] Dai Mei-ling, Cheng Cheng, Wu Zhi-wen, Lu Zhen-wei, Lu Jie-xun, Yang Jian, Yang Fu-jun. Quasi-static Compressive Mechanical Behaviors of Perforated Hollow-Sphere Structures [J]. Journal of Guangdong University of Technology, 2022, 39(04): 83-90,97.
[5] Cao Yi-ting, Wang Qiao, Xu Ze-tao, Lyu Guan-heng. Research Progress of MOF/Bismuth-based Semiconductor Composites in Photocatalytic Technology [J]. Journal of Guangdong University of Technology, 2022, 39(04): 113-120.
[6] Cai Mei-ling, Li Yu-xiu, Ma Ao-jie, Chen Song-jia, Huang Shi-zhao, Chen Ying. A Molecular Dynamics Simulation on Wettability of a Liquid Droplet on Solid Surface with Nanoscale Inverted Triangular Grooves [J]. Journal of Guangdong University of Technology, 2022, 39(04): 121-127.
[7] Luo Chao-bing, Li Hai-chao, You Ting-ting, Xu Feng. Progress on Lignin Deep Eutectic Solvent Fractionation, Functional Materials Preparation and Industrial Application [J]. Journal of Guangdong University of Technology, 2022, 39(01): 1-13.
[8] Hao Yan-ping, Luo Tong, Lyu Gao-jin, Wang Chao, Zhou Hao, Yang Gui-hua, Chen Jia-chuan. Research Progress of Lignin-derived Biodegradable Composite Film Materials [J]. Journal of Guangdong University of Technology, 2022, 39(01): 21-33.
[9] Liu Xue, Liu Zhong-ming, Xi Yue-bin, Wang Shou-juan, Kong Fan-gong. A Study of Preparation and Application Performance of Lignin-based Superhydrophobic Coatings [J]. Journal of Guangdong University of Technology, 2022, 39(01): 34-40,134.
[10] Yu Jian, Chen Ze-hong, Peng Xin-wen. Application of Biomass-based Energy Storage Materials in Flexible Devices [J]. Journal of Guangdong University of Technology, 2022, 39(01): 41-49.
[11] Chen Zi-li, Zhang Guang-yu, Liu Yi-xin. A Research on the Subversive Innovation Mode of NEV Enterprises—Based on the Comparative Analysis of Representative Enterprises in China, America and Japan [J]. Journal of Guangdong University of Technology, 2021, 38(05): 108-118.
[12] Liao Zi-feng, Zhao Wei-ren, Huang Hao, Song Jing-zhou. Heavy Mn-Doped Ca14Zn6Al10O35 Phosphor and Its Near-Infrared II Light Emission [J]. Journal of Guangdong University of Technology, 2021, 38(01): 97-103,110.
[13] Zhu Can, Lin Hao-hui, Xiang Lin-Fang. Research Process and Forward Trends of New Energy Vehicles Based on the Knowledge Map Analysis of Citespace Ⅲ [J]. Journal of Guangdong University of Technology, 2020, 37(02): 45-52.
[14] Huang Jin, Zhou Hua, Liu Kai-zhao, Xiao Hui-wu, Hu Yan-xin. An Experimental Study of Gas-Cooled Thermoelectric Power Generation Stove [J]. Journal of Guangdong University of Technology, 2020, 37(02): 53-59.
[15] Liang Bo-xin, Yi Shuang-ping, Hu Geng-qiao, Fang Zhi-xiong, Zhao Wei-ren. Synthesis and Luminescence Properties of Multicolor Tunable ZnNb2O6: Dy3+, Eu3+ Phosphors Based on Energy Transfer [J]. Journal of Guangdong University of Technology, 2020, 37(01): 34-41.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
No Suggested Reading articles found!
Copyright © 2017 Journal of Guangdong University of Technology
Add:729 East Dongfeng RD., Guangzhou PRC. Postcode: 510090
Tel:020-37626653,020-37626139,020-37626396
Email:xbzrb@gdut.edu.cn
Supported:Beijing Magtech