Research progress of non-aqueous solvents on the pretreatment of lignocellulose

doi:10.16085/j.issn.1000-6613.2021-1969

Abstract

Abstract:

Lignocellulose is the most abundant renewable resource in China. However, the intertwined complex structures prevent further conversion of cellulose and hemicellulose inside, which makes researchers seek effective pretreatment methods to solve the current problem. With the continuous discovery of solvents for biomass pretreatment and the emergence of new solvents, non-aqueous solvent pretreatment as an emerging pretreatment method has shown good effects and application prospects in the biorefinery of lignocellulosic raw materials. In this paper, based on introducing the physicochemical properties of various non-aqueous solvents, recent advances on the effect of these solvents on the pretreatment of lignocellulose, including the performance for hemicellulose and lignin removal and their influence on enzymatic hydrolysis are reviewed. The main advantages and disadvantages of different non-aqueous solvent pretreatment are also summarized. Furthermore, the challenges and future development directions of non-aqueous solvent pretreatment are proposed, which would provide references and guidance for future green, low-cost and efficient pretreatment methods.

Key words: lignocellulose, pretreatment, non-aqueous solvent, alcohols, organic acid, ionic liquid

摘要：

木质纤维素是目前中国最丰富的可再生资源，但由于其交织的复杂结构阻碍了内部纤维素和半纤维素的后续转化，这促使研究者们去寻求有效的预处理方法以解决目前的困境。近年来，随着预处理溶剂不断被发现和新型溶剂的快速涌现，非水溶剂预处理作为一种新兴的预处理方式在木质纤维素生物炼制中展现出良好的效果和应用前景。本文在系统介绍了各种非水溶剂理化性质和特点的基础上，综述了各种非水溶剂对木质纤维素预处理的作用原理、半纤维素和木质素的去除效果以及对纤维素酶解性能的影响，同时总结归纳了不同非水溶剂预处理的主要优缺点，并对非水溶剂预处理面临的挑战和未来的发展方向进行了展望，以期对未来绿色、低廉、高效的预处理方法提供借鉴和指导。

关键词: 木质纤维素, 预处理, 非水溶剂, 醇类, 有机酸, 离子液体

CLC Number:

HAN Mingyang, QIAO Hui, FU Jiaming, MA Zewen, WANG Yan, OUYANG Jia. Research progress of non-aqueous solvents on the pretreatment of lignocellulose[J]. Chemical Industry and Engineering Progress, 2022, 41(8): 4086-4097.

韩明阳, 乔慧, 付佳铭, 马泽雯, 王妍, 欧阳嘉. 非水溶剂预处理木质纤维原料研究进展[J]. 化工进展, 2022, 41(8): 4086-4097.

Figures/Tables 6

References 81

1	国家发展和改革委员会. 可再生能源中长期发展规划[J]. 可再生能源, 2007, 25(5): 1-5.
	National Development and Reform Commission. Medium and long-term development plan for renewable energy[J]. Renewable Energy Resources, 2007, 25(5): 1-5.
2	SOLTANIAN S, AGHBASHLO M, ALMASI F, et al. A critical review of the effects of pretreatment methods on the exergetic aspects of lignocellulosic biofuels[J]. Energy Conversion and Management, 2020, 212: 112792.
3	KARAGOZ P, BILL R M, OZKAN M. Lignocellulosic ethanol production: evaluation of new approaches, cell immobilization and reactor configurations[J]. Renewable Energy, 2019, 143: 741-752.
4	MANKAR A R, PANDEY A, MODAK A, et al. Pretreatment of lignocellulosic biomass: a review on recent advances[J]. Bioresource Technology, 2021, 334: 125235.
5	MORENO A D, OLSSON L. Pretreatment of lignocellulosic feedstocks[M]. Belin: Springer International Publishing, 2017.
6	GALBE M, WALLBERG O. Pretreatment for biorefineries: a review of common methods for efficient utilisation of lignocellulosic materials[J]. Biotechnology for Biofuels, 2019, 12: 294.
7	曹运齐, 解先利, 郭振强, 等. 木质纤维素预处理技术研究进展[J]. 化工进展, 2020, 39(2): 489-495.
	CAO Yunqi, XIE Xianli, GUO Zhenqiang, et al. Research progress on lignocellulose pretreatment technology[J]. Chemical Industry and Engineering Progress, 2020, 39(2): 489-495.
8	ZHAO Xuebing, CHENG Keke, LIU Dehua. Organosolv pretreatment of lignocellulosic biomass for enzymatic hydrolysis[J]. Applied Microbiology and Biotechnology, 2009, 82(5): 815-827.
9	MELLMER M A, MARTIN ALONSO D, LUTERBACHER J S, et al. Effects of γ-valerolactone in hydrolysis of lignocellulosic biomass to monosaccharides[J]. Green Chemistry, 2014, 16(11): 4659-4662.
10	ZHANG Zhanying, HARRISON M D, RACKEMANN D W, et al. Organosolv pretreatment of plant biomass for enhanced enzymatic saccharification[J]. Green Chemistry, 2016, 18(2): 360-381.
11	DURAND M, MOLINIER V, KUNZ W, et al. Classification of organic solvents revisited by using the COSMO-RS approach[J]. Chemistry, 2011, 17(18): 5155-5164.
12	赵地顺, 付林林, 张娟, 等. 共溶剂存在下N-烯丙基吡啶氯盐离子液体对纤维素的溶解性能研究[J]. 高分子学报, 2012(9): 937-942.
	ZHAO Dishun, FU Linlin, ZHANG Juan, et al. Study on the dissolution of cellulose in N-allylpyridinium chloride ionic liquid and co-solvent composites[J]. Acta Polymerica Sinica, 2012(9): 937-942.
13	ZHAO Xuebing, LI Siming, WU Ruchun, et al. Organosolv fractionating pre-treatment of lignocellulosic biomass for efficient enzymatic saccharification: chemistry, kinetics, and substrate structures[J]. Biofuels, Bioproducts and Biorefining, 2017, 11(3): 567-590.
14	JESSOP P G, JESSOP D A, FU Dongbao, et al. Solvatochromic parameters for solvents of interest in green chemistry[J]. Green Chemistry, 2012, 14(5): 1245.
15	WEI Weiqi, WU Shubin, XU Shaohua. Enhancement of enzymatic saccharification of bagasse by ethanol-based organosolv auto-catalyzed pretreatment[J]. Journal of Chemical Technology & Biotechnology, 2017, 92(3): 580-587.
16	ZHANG Hongdan, WU Shubin. Efficient sugar release by acetic acid ethanol-based organosolv pretreatment and enzymatic saccharification[J]. Journal of Agricultural and Food Chemistry, 2014, 62(48): 11681-11687.
17	CHOI J H, JANG S K, KIM J H, et al. Simultaneous production of glucose, furfural, and ethanol organosolv lignin for total utilization of high recalcitrant biomass by organosolv pretreatment[J]. Renewable Energy, 2019, 130: 952-960.
18	ZHANG Hongdan, WEI Weiqi, ZHANG Jiajie, et al. Enhancing enzymatic saccharification of sugarcane bagasse by combinatorial pretreatment and Tween 80[J]. Biotechnology for Biofuels, 2018, 11: 309.
19	ZHANG Jiajie, XIE Jun, ZHANG Hongdan. Sodium hydroxide catalytic ethanol pretreatment and surfactant on the enzymatic saccharification of sugarcane bagasse[J]. Bioresource Technology, 2021, 319: 124171.
20	TANG Chenglun, SHAN Junqiang, CHEN Yanjun, et al. Organic amine catalytic organosolv pretreatment of corn stover for enzymatic saccharification and high-quality lignin[J]. Bioresource Technology, 2017, 232: 222-228.
21	YOU Yanzhi, LI Pengfei, LEI Fuhou, et al. Optimization of enzymatic hydrolysis on sugarcane bagasse pretreated with soda-green liquor and methanol[J]. Journal of Biobased Materials and Bioenergy, 2017, 11(5): 433-440.
22	ZHONG Lei, WANG Chao, XU Miaomiao, et al. Alkali-catalyzed organosolv pretreatment of lignocellulose enhances enzymatic hydrolysis and results in highly antioxidative lignin[J]. Energy & Fuels, 2021, 35(6): 5039-5048.
23	杨博. 木质素组装对纤维素酶水解促进机制的研究[D]. 南京: 南京林业大学, 2019.
	YANG Bo. Study on the mechanism of cellulase hydrolysis promoted by lignin assembly[D]. Nanjing: Nanjing Forestry University, 2019.
24	ZHOU Ziyuan, LEI Fuhou, LI Pengfei, et al. Lignocellulosic biomass to biofuels and biochemicals: a comprehensive review with a focus on ethanol organosolv pretreatment technology[J]. Biotechnology and Bioengineering, 2018, 115(11): 2683-2702.
25	PARK Y C, KIM T H, KIM J S. Effect of organosolv pretreatment on mechanically pretreated biomass by use of concentrated ethanol as the solvent[J]. Biotechnology and Bioprocess Engineering, 2017, 22(4): 431-439.
26	SILVEIRA M H L, MORAIS A R C, COSTA LOPES A M DA, et al. Current pretreatment technologies for the development of cellulosic ethanol and biorefineries[J]. ChemSusChem, 2015, 8(20): 3366-3390.
27	JÖNSSON L J, MARTÍN C. Pretreatment of lignocellulose: formation of inhibitory by-products and strategies for minimizing their effects[J]. Bioresource Technology, 2016, 199: 103-112.
28	WANG Yunbo, GUO Xiaojun, LI Kaijia, et al. Comparison of a solvent mixture assisted dilute acid and alkali pretreatment in sugar production from hybrid Pennisetum [J]. Industrial Crops and Products, 2019, 141: 111806
29	AGIRREZABAL-TELLERIA I, GANDARIAS I, ARIAS P L. Heterogeneous acid-catalysts for the production of furan-derived compounds (furfural and hydroxymethylfurfural) from renewable carbohydrates: a review[J]. Catalysis Today, 2014, 234: 42-58.
30	KIM J S, LEE Y Y, KIM T H. A review on alkaline pretreatment technology for bioconversion of lignocellulosic biomass[J]. Bioresource Technology, 2016, 199: 42-48.
31	SANNIGRAHI P, KIM D H, JUNG S, et al. Pseudo-lignin and pretreatment chemistry[J]. Energy & Environmental Science, 2011, 4(4): 1306-1310.
32	PARK Y, KIM J, KIM T. Pretreatment of corn stover using organosolv with hydrogen peroxide for effective enzymatic saccharification[J]. Energies, 2018, 11(5): 1301.
33	BORAND M N, KARAOSMANOĞLU F. Effects of organosolv pretreatment conditions for lignocellulosic biomass in biorefinery applications: a review[J]. Journal of Renewable and Sustainable Energy, 2018, 10(3): 033104.
34	ZHANG Ke, PEI Zhijian, WANG Donghai. Organic solvent pretreatment of lignocellulosic biomass for biofuels and biochemicals: a review[J]. Bioresource Technology, 2016, 199: 21-33.
35	MANSOURI N E EL, SALVADÓ J. Analytical methods for determining functional groups in various technical lignins[J]. Industrial Crops and Products, 2007, 26(2): 116-124.
36	GAO Cuijuan, YANG Xiaofeng, WANG Huaimin, et al. Robust succinic acid production from crude glycerol using engineered Yarrowia lipolytica [J]. Biotechnology for Biofuels, 2016, 9(1): 179.
37	JIANG Liqun, WU Yaxiang, WANG Xiaobo, et al. Crude glycerol pretreatment for selective saccharification of lignocellulose via fast pyrolysis and enzyme hydrolysis[J]. Energy Conversion and Management, 2019, 199: 111894.
38	SUN Fubao, CHEN Hongzhang. Enhanced enzymatic hydrolysis of wheat straw by aqueous glycerol pretreatment[J]. Bioresource Technology, 2008, 99(14): 6156-6161.
39	EBRAHIMI M, VILLAFLORES O B, ORDONO E E, et al. Effects of acidified aqueous glycerol and glycerol carbonate pretreatment of rice husk on the enzymatic digestibility, structural characteristics, and bioethanol production[J]. Bioresource Technology, 2017, 228: 264-271.
40	PASCAL K, REN Hongyan, SUN F F, et al. Mild acid-catalyzed atmospheric glycerol organosolv pretreatment effectively improves enzymatic hydrolyzability of lignocellulosic biomass[J]. ACS Omega, 2019, 4(22): 20015-20023.
41	SUN F F, WANG Liang, HONG Jiapeng, et al. The impact of glycerol organosolv pretreatment on the chemistry and enzymatic hydrolyzability of wheat straw[J]. Bioresource Technology, 2015, 187: 354-361.
42	HII K L, YEAP S P, MASHITAH M D. Pretreatment of pressed pericarp fibers (PPF) using alcohols as solvent to increase the accessibility of cellulose for cellulase production[J]. Journal of the Korean Society for Applied Biological Chemistry, 2012, 55(4): 507-514.
43	XUE Fengyang, LI Wenzhi, AN Shengxin, et al. Ethylene glycol based acid pretreatment of corn stover for cellulose enzymatic hydrolysis[J]. RSC Advances, 2021, 11(23): 14140-14147.
44	WEI Weiqi, WANG Baoxian, WANG Xiaoxiang, et al. Comparison of acid and alkali catalyzed ethylene glycol organosolv pretreatment for sugar production from bagasse[J]. Bioresource Technology, 2021, 320(Pt A): 124293.
45	TANG Song, DONG Qian, FANG Zhen, et al. Complete recovery of cellulose from rice straw pretreated with ethylene glycol and aluminum chloride for enzymatic hydrolysis[J]. Bioresource Technology, 2019, 284: 98-104.
46	ZHANG Jiaguang, YAN Ning. Formic acid-mediated liquefaction of chitin[J]. Green Chemistry, 2016, 18(18): 5050-5058.
47	ZHAO Xuebing, MORIKAWA Y, QI Feng, et al. A novel kinetic model for polysaccharide dissolution during atmospheric acetic acid pretreatment of sugarcane bagasse[J]. Bioresource Technology, 2014, 151: 128-136.
48	PATHAK P, GUPTA A, BHARDWAJ N K, et al. Impact of mild and harsh conditions of formic acid-based organosolv pretreatment on biomass fractionation of sugarcane tops[J]. Biomass Conversion and Biorefinery, 2021, 11(5): 2027-2040.
49	ZHAO Xuebing, LIU Dehua. Fractionating pretreatment of sugarcane bagasse by aqueous formic acid with direct recycle of spent liquor to increase cellulose digestibility: the Formiline process[J]. Bioresource Technology, 2012, 117: 25-32.
50	QIAO Hui, OUYANG Shuiping, SHI Jinjie, et al. Mild and efficient two-step pretreatment of lignocellulose using formic acid solvent followed by alkaline salt[J]. Cellulose, 2021, 28(3): 1283-1293.
51	CHEN Changzhou, LI Mingfei, WU Yuying, et al. Integration of ambient formic acid process and alkaline hydrogen peroxide post-treatment of furfural residue to enhance enzymatic hydrolysis[J]. Industrial & Engineering Chemistry Research, 2014, 53(33): 12935-12942.
52	TANG Song, LIU Rukuan, SUN F F, et al. Bioprocessing of tea oil fruit hull with acetic acid organosolv pretreatment in combination with alkaline H₂O₂ [J]. Biotechnology for Biofuels, 2017, 10: 86.
53	ZHAO Xuebing, WEN Jialong, CHEN Hongmei, et al. The fate of lignin during atmospheric acetic acid pretreatment of sugarcane bagasse and the impacts on cellulose enzymatic hydrolyzability for bioethanol production[J]. Renewable Energy, 2018, 128: 200-209.
54	MOTA T R, OLIVEIRA D M, MORAIS G R, et al. Hydrogen peroxide-acetic acid pretreatment increases the saccharification and enzyme adsorption on lignocellulose[J]. Industrial Crops and Products, 2019, 140: 111657.
55	BAEZA J, ANA M F, FREER J, et al. Organosolv-pulping iii—The influence of formic acid delignification on the enzymatic hydrolysis of Pinus radiata D. Don sawdust[J]. Applied Biochemistry & Biotechnology, 1991, 31(3): 273-282.
56	ZHAO Xuebing, LIU Dehua. Multi-products co-production improves the economic feasibility of cellulosic ethanol: a case of Formiline pretreatment-based biorefining[J]. Applied Energy, 2019, 250: 229-244.
57	ZHAO Xuebing, LIU Dehua. Kinetic modeling and mechanisms of acid-catalyzed delignification of sugarcane bagasse by aqueous acetic acid[J]. BioEnergy Research, 2013, 6(2): 436-447.
58	SMIT A, HUIJGEN W. Effective fractionation of lignocellulose in herbaceous biomass and hardwood using a mild acetone organosolv process[J]. Green Chemistry, 2017, 19(22): 5505-5514.
59	GONG Chen, GOUNDALKAR M J, BUJANOVIC B M, et al. Evaluation of different sulfur-free delignification methods for hot-water extracted hardwood[J]. Journal of Wood Chemistry and Technology, 2012, 32(2): 93-104.
60	HUIJGEN W J J, REITH J H, DEN UIL H. Pretreatment and fractionation of wheat straw by an acetone-based organosolv process[J]. Industrial & Engineering Chemistry Research, 2010, 49(20): 10132-10140.
61	KALOGIANNIS K G, MATSAKAS L, ASPDEN J, et al. Acid assisted organosolv delignification of beechwood and pulp conversion towards high concentrated cellulosic ethanol via high gravity enzymatic hydrolysis and fermentation[J]. Molecules, 2018, 23(7): 1647.
62	TENG Junjiang, MA Hao, WANG Furong, et al. Catalytic fractionation of raw biomass to biochemicals and organosolv lignin in a methyl isobutyl ketone/H₂O biphasic system[J]. ACS Sustainable Chemistry & Engineering, 2016, 4(4): 2020-2026.
63	PISKUN A S, FTOUNI J, TANG Z, et al. Hydrogenation of levulinic acid to γ-valerolactone over anatase-supported Ru catalysts: effect of catalyst synthesis protocols on activity[J]. Applied Catalysis A: General, 2018, 549: 197-206.
64	SHUAI Li, QUESTELL-SANTIAGO Y M, LUTERBACHER J S. A mild biomass pretreatment using γ-valerolactone for concentrated sugar production[J]. Green Chemistry, 2016, 18(4): 937-943.
65	LI Suxiang, ZHAO Chengke, YUE Fengxia, et al. Revealing structural modifications of lignin in acidic γ-valerolactone-H₂O pretreatment[J]. Polymers, 2020, 12(1): 116.
66	XU Zhiping, LI Wenzhi, DU Zhijie, et al. Conversion of corn stalk into furfural using a novel heterogeneous strong acid catalyst in γ-valerolactone[J]. Bioresource Technology, 2015, 198: 764-771.
67	张毅, 张宏, 刘云云, 等. 纤维素燃料乙醇预处理技术研究进展[J]. 可再生能源, 2021, 39(2): 148-155.
	ZHANG Yi, ZHANG Hong, LIU Yunyun, et al. Research progress of cellulosic fuel ethanol pretreatment technology[J]. Renewable Energy Resources, 2021, 39(2): 148-155.
68	PAUL A, MUTHUKUMAR S, PRASAD S. Review—Room-temperature ionic liquids for electrochemical application with special focus on gas sensors[J]. Journal of the Electrochemical Society, 2020, 167(3): 037511.
69	SWATLOSKI R P, SPEAR S K, HOLBREY J D, et al. Dissolution of cellulose[correction of cellose]with ionic liquids[J]. Journal of the American Chemical Society, 2002, 124(18): 4974-4975.
70	ALAYOUBI R, MEHMOOD N, HUSSON E, et al. Low temperature ionic liquid pretreatment of lignocellulosic biomass to enhance bioethanol yield[J]. Renewable Energy, 2020, 145: 1808-1816.
71	BHATIA S K, JAGTAP S S, BEDEKAR A A, et al. Recent developments in pretreatment technologies on lignocellulosic biomass: effect of key parameters, technological improvements, and challenges[J]. Bioresource Technology, 2020, 300: 122724.
72	YAVIR K, MARCINKOWSKI Ł, MARCINKOWSKA R, et al. Analytical applications and physicochemical properties of ionic liquid-based hybrid materials: a review[J]. Analytica Chimica Acta, 2019, 1054: 1-16.
73	SUN Xiyan, SUN Xitong, ZHANG Fan. Combined pretreatment of lignocellulosic biomass by solid base (calcined Na₂SiO₃) and ionic liquid for enhanced enzymatic saccharification[J]. RSC Advances, 2016, 6(101): 99455-99466.
74	GROFF D, GEORGE A, SUN Ning, et al. Acid enhanced ionic liquid pretreatment of biomass[J]. Green Chemistry, 2013, 15(5): 1264.
75	董艳梅, 安艳霞, 马阳阳, 等. 深度共熔溶剂预处理木质纤维素生物质研究进展[J]. 化工进展, 2021, 40(3): 1594-1603.
	DONG Yanmei, AN Yanxia, MA Yangyang, et al. Research progress on deep eutectic solvent of lignocellulose pretreatment[J]. Chemical Industry and Engineering Progress, 2021, 40(3): 1594-1603.
76	CHEN Wenjun, XUE Zhimin, WANG Jinfang, et al. Investigation on the thermal stability of deep eutectic solvents[J]. Acta Physico-Chimica Sinica, 2018, 34(8): 904-911.
77	ZHU Jiahong, XU Yingjie, FENG Xiao, et al. A detailed study of physicochemical properties and microstructure of EmimCl-EG deep eutectic solvents: their influence on SO₂ absorption behavior[J]. Journal of Industrial and Engineering Chemistry, 2018, 67: 148-155.
78	YU Dongkun, MU Tiancheng. Strategy to form eutectic molecular liquids based on noncovalent interactions[J]. The Journal of Physical Chemistry B, 2019, 123(23): 4958-4966.
79	CHEN Zhu, JACOBY W A, WAN Caixia. Ternary deep eutectic solvents for effective biomass deconstruction at high solids and low enzyme loadings[J]. Bioresource Technology, 2019, 279: 281-286.
80	CHEN Zhu, WAN Caixia. Ultrafast fractionation of lignocellulosic biomass by microwave-assisted deep eutectic solvent pretreatment[J]. Bioresource Technology, 2018, 250: 532-537.
81	MALAEKE H, HOUSAINDOKHT M R, MONHEMI H, et al. Deep eutectic solvent as an efficient molecular liquid for lignin solubilization and wood delignification[J]. Journal of Molecular Liquids, 2018, 263: 193-199.

溶剂	化学式	介电常数（ε_r）	Hildebrand溶解参数/MPa^1/2	极性参数E_T(30)/kcal·mol^-1	沸点/℃	闪点/℃
乙醇	C₂H₆O	24.55	26.5	0.654	78.3	12
甲醇	CH₄O	32.66	29.6	0.762	64.5	11.1
丙三醇	C₃H₈O₃	47	36.1	0.817	290	176
乙二醇	C₂H₆O₂	37.7	32.9	0.79	197.3	111.1
甲酸	CH₂O₂	58.5（16℃）	24.9	0.833	100.6	69
乙酸	C₂H₄O₂	6.17（20℃）	21.4	0.648	117.9	39
丙酮	C₃H₆O	20.56	20	0.355	56.5	-20
甲基异丁基酮	C₆H₁₂O	13.11（20℃）	17.4	0.179	116.5	13.3
γ-戊内酯	C₅H₈O₂	—	—	—	207	81
甲基四氢呋喃	C₅H₁₀O	6.97	—	—	80	-11

溶剂	化学式	介电常数（ε_r）	Hildebrand溶解参数/MPa^1/2	极性参数E_T(30)/kcal·mol^-1	沸点/℃	闪点/℃
乙醇	C₂H₆O	24.55	26.5	0.654	78.3	12
甲醇	CH₄O	32.66	29.6	0.762	64.5	11.1
丙三醇	C₃H₈O₃	47	36.1	0.817	290	176
乙二醇	C₂H₆O₂	37.7	32.9	0.79	197.3	111.1
甲酸	CH₂O₂	58.5（16℃）	24.9	0.833	100.6	69
乙酸	C₂H₄O₂	6.17（20℃）	21.4	0.648	117.9	39
丙酮	C₃H₆O	20.56	20	0.355	56.5	-20
甲基异丁基酮	C₆H₁₂O	13.11（20℃）	17.4	0.179	116.5	13.3
γ-戊内酯	C₅H₈O₂	—	—	—	207	81
甲基四氢呋喃	C₅H₁₀O	6.97	—	—	80	-11

溶剂（体积分数）	催化剂（质量分数）	底物	预处理条件	半纤维素去除率/%	木质素去除率/%	纤维素酶解得率/%	参考文献
40%乙醇	—	甘蔗渣	195℃，30min	66.25	47.79	92.2	［15］
50%乙醇	—	甘蔗渣	190℃，45min	72.1	50.1	90.83	［16］
60%乙醇	—	甘蔗渣	190℃，45min	56.3	44.6	92.50	［16］
70%乙醇	—	甘蔗渣	190℃，45min	42.3	42.8	46.04	［16］
80%乙醇	—	甘蔗渣	190℃，45min	24.7	21.2	33.09	［16］
50%乙醇	—	桉树	170℃，10min	18.9	21.1	8.1	［17］
50%乙醇	1% H₂SO₄	桉树	140℃，10min	90.2	70.0	55.6	［17］
50%乙醇	1% H₂SO₄	桉树	150℃，10min	96.6	74.0	62.1	［17］
50%乙醇	1% H₂SO₄	桉树	160℃，10min	98.3	83.3	77.5	［17］
50%乙醇	1% H₂SO₄	桉树	170℃，10min	99.2	80.7	75.8	［17］
60%乙醇	—	甘蔗渣	120℃，60min	13.4	2.5	23.6	［18］
60%乙醇	5%NaOH	甘蔗渣	120℃，60min	22.6	17.9	72.0	［18］
60%乙醇	5% NaOH	甘蔗渣	180℃，30min	92.9	71.8	93.0	［19］
60%乙醇	正丙胺	玉米秸秆	140℃，40min	78.9	81.7	83.2	［20］
50%甲醇	碱性液体	甘蔗渣	120℃，180min	—	82.75	92.82	［21］
50%甲醇	2% NaOH	菜花废弃物	80℃，90min	—	86.7	97.9	［22］

溶剂（体积分数）	催化剂（质量分数）	底物	预处理条件	半纤维素去除率/%	木质素去除率/%	纤维素酶解得率/%	参考文献
40%乙醇	—	甘蔗渣	195℃，30min	66.25	47.79	92.2	［15］
50%乙醇	—	甘蔗渣	190℃，45min	72.1	50.1	90.83	［16］
60%乙醇	—	甘蔗渣	190℃，45min	56.3	44.6	92.50	［16］
70%乙醇	—	甘蔗渣	190℃，45min	42.3	42.8	46.04	［16］
80%乙醇	—	甘蔗渣	190℃，45min	24.7	21.2	33.09	［16］
50%乙醇	—	桉树	170℃，10min	18.9	21.1	8.1	［17］
50%乙醇	1% H₂SO₄	桉树	140℃，10min	90.2	70.0	55.6	［17］
50%乙醇	1% H₂SO₄	桉树	150℃，10min	96.6	74.0	62.1	［17］
50%乙醇	1% H₂SO₄	桉树	160℃，10min	98.3	83.3	77.5	［17］
50%乙醇	1% H₂SO₄	桉树	170℃，10min	99.2	80.7	75.8	［17］
60%乙醇	—	甘蔗渣	120℃，60min	13.4	2.5	23.6	［18］
60%乙醇	5%NaOH	甘蔗渣	120℃，60min	22.6	17.9	72.0	［18］
60%乙醇	5% NaOH	甘蔗渣	180℃，30min	92.9	71.8	93.0	［19］
60%乙醇	正丙胺	玉米秸秆	140℃，40min	78.9	81.7	83.2	［20］
50%甲醇	碱性液体	甘蔗渣	120℃，180min	—	82.75	92.82	［21］
50%甲醇	2% NaOH	菜花废弃物	80℃，90min	—	86.7	97.9	［22］

溶剂	催化剂	底物	预处理条件	半纤维素去除率/%	木质素去除率/%	纤维素酶解得率/%	参考文献
100%甘油	—	麦草	240℃，4h	—	70	90	［40］
100%甘油	0.02% H₂SO₄	甘蔗渣	160℃，30min	67	28	—	［40］
100%甘油	0.04% H₂SO₄	甘蔗渣	160℃，30min	83	31	—	［40］
100%甘油	0.06% H₂SO₄	甘蔗渣	200℃，15min	82	52	70	［40］
80%乙二醇	—	玉米秸秆	120℃，60min	7.5	27.7	—	［43］
80%乙二醇	0.6% H₂SO₄	玉米秸秆	120℃，60min	81.3	80.3	70.6	［43］
90%乙二醇	—	甘蔗渣	150℃，60min	6.5	3.6	29.8	［44］
90%乙二醇	1mol/L HCl	甘蔗渣	150℃，60min	99.3	67.1	80.1	［44］
90%乙二醇	1mol/L NaOH	甘蔗渣	150℃，60min	28.8	90.9	90.0	［44］
90%乙二醇	0.006mol/L AlCl₃	稻草	150℃，30min	0.2	35.0	—	［45］
90%乙二醇	0.028mol/L AlCl₃	稻草	150℃，30min	82.4	83.5	—	［45］
90%乙二醇	0.055mol/L AlCl₃	稻草	150℃，30min	90.1	87.7	94	［45］