{"id":94,"date":"2010-06-02T19:39:27","date_gmt":"2010-06-02T11:39:27","guid":{"rendered":"http:\/\/brg.groups.xtbg.ac.cn\/%e7%a0%94%e7%a9%b6%e6%96%b9%e5%90%91-2"},"modified":"2026-02-14T13:04:30","modified_gmt":"2026-02-14T05:04:30","slug":"%e7%a0%94%e7%a9%b6%e6%96%b9%e5%90%91-2","status":"publish","type":"page","link":"https:\/\/woodrefinery.com\/zhenfang\/%e7%a0%94%e7%a9%b6%e6%96%b9%e5%90%91-2\/","title":{"rendered":"Interests"},"content":{"rendered":"<p style=\"text-align: justify;\"><strong>1.Hydrolysis of lignocellulosic wastes<\/strong><\/p>\n<p style=\"text-align: justify;\">Fast hydrolysis, low-temperature hydrolysis with catalysts and enzymatic hydrolysis are studied. The sugars produced are biologically converted to biofuels and chemicals (such as bio-hydrogen, ethanol and 2,3 butanediol).<\/p>\n<p style=\"text-align: justify;\">(1) Fast hydrolysis (e.g., 350 <sup><span style=\"font-size: small;\">o<\/span><\/sup>C)<\/p>\n<p style=\"text-align: justify;\">(2) Low-temperature hydrolysis with catalysts (e.g., 150 <sup><span style=\"font-size: small;\">o<\/span><\/sup>C)<\/p>\n<p style=\"text-align: justify;\">(3) Enzymatic hydrolysis (e.g., 50 <sup><span style=\"font-size: small;\">o<\/span><\/sup>C)<\/p>\n<p style=\"text-align: justify;\"><strong>2.Synthesis of biodiesel <\/strong><\/p>\n<ul class=\" list-paddingleft-2\" style=\"text-align: justify;\">\n<li>Heterogeneous nano or magnetic catalysts (such as magnetic carbonaceous acid, calcined\/activated hydrotalcite nanoparticles, Na<sub><span style=\"font-size: small;\">2<\/span><\/sub>SiO<sub><span style=\"font-size: small;\">3<\/span><\/sub>@Fe<sub><span style=\"font-size: small;\">3<\/span><\/sub>O<sub><span style=\"font-size: small;\">4<\/span><\/sub>\/C, CaFe<sub><span style=\"font-size: small;\">2<\/span><\/sub>O<sub><span style=\"font-size: small;\">4<\/span><\/sub>-Ca<sub><span style=\"font-size: small;\">2<\/span><\/sub>Fe<sub><span style=\"font-size: small;\">2<\/span><\/sub>O<sub><span style=\"font-size: small;\">5<\/span><\/sub>-based catalyst) are produced <em>via<\/em> different methods (such as co-precipitation, hydrothermal, calcinations, loading).<\/li>\n<\/ul>\n<p style=\"text-align: justify;\"><strong>3.Chemical synthesis of value-added products from lignocellulosic wastes<\/strong><\/p>\n<ul class=\" list-paddingleft-2\" style=\"text-align: justify;\">\n<li>Value-added products (such as 5-hydroxymethylfurfural, biochar, acids, furfural, alkyl levulinates and \u03b3-valerolactone (GVL) etc.) are synthesized in green solvents with acid, base and bi-functional heterogeneous catalysts (such as modified zeolites, ZrO<sub><span style=\"font-size: small;\">2<\/span><\/sub>-zeolite hybrids).<\/li>\n<\/ul>\n<p style=\"text-align: justify;\"><strong>4.Biological production of biofuels from hydrolysates and organic wastes <\/strong><\/p>\n<ul class=\" list-paddingleft-2\" style=\"text-align: justify;\">\n<li>Biofuels and chemicals (such as bio-hydrogen, ethanol, 2,3 butanediol, lipids) are produced <em>via<\/em> fermentation of hydrolysates and organic wastes.<\/li>\n<\/ul>\n<p style=\"text-align: justify;\"><strong>5.Thermal conversions of biomass and organic wastes <\/strong><\/p>\n<p style=\"text-align: justify;\">(1) Fast pyrolysis<\/p>\n<p style=\"text-align: justify;\">(2) Slow pyrolysis for biochar production<\/p>\n<p style=\"text-align: justify;\">(3) H<sub><span style=\"font-size: small;\">2<\/span><\/sub> production from organic wastes<\/p>\n<p style=\"text-align: justify;\">(4) Supercritical water oxidation (SCW oxidation) of toxic organic wastes<\/p>\n<p style=\"text-align: justify;\"><strong>6.Hydrothermally solubilize biomass, and subsequently convert it to biofuels and chemicals<\/strong><\/p>\n<p style=\"text-align: justify;\"><strong>7.Nano or micro catalysts synthesis using hydrothermal method or other conventional ways (e.g., precipitation and calcination)<\/strong><\/p>\n<p style=\"text-align: justify;\"><strong>8.Energy planning and policy, Techno-economic analysis <\/strong><\/p>\n<p style=\"text-align: justify;\">\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014\u2014<\/p>\n<p style=\"text-align: justify;\"><strong>THEORETICAL CONTRIBUTIONS:<\/strong><\/p>\n<p style=\"text-align: justify;\"><strong>\u00a0<\/strong><\/p>\n<p style=\"text-align: justify;\">Biomass group has made significant contributions to the fields of hydrolysis of lignocellulosic biomass, biodiesel synthesis and liquid biofuel production, supercritical fluid processes, catalyst synthesis and nanomaterials.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">1.Pioneered the synthesis of nitrogen-containing compounds and liquid fuels at low temperature from carbohydrates (Nat Commun; PCT\/CN2017\/106729, PCT\/CN2019\/098614, 2 CN patents). With or without nanocatalysts, lignocellulose can be almost completely converted into imines and liquid fuels after hydrolysis and decomposition (e.g., 2,5-dimethylfuran, methyl levulinate, \u03b3-valerolactone, methylfuran).<\/p>\n<p style=\"text-align: justify;\">1)Discovery and reaction mechanism of N-formyl quasi-catalytic species<\/p>\n<p style=\"text-align: justify;\">As an important industrial raw material, primary amines have a wide range of applications in medicines, polymers, and functional materials. Generally, primary amines can be prepared by metal-catalyzed reductive amination, but there are problems such as expensive metal catalysts and complicated preparation processes. According to the above problem, we developed a green process for the production of primary amines under catalyst-free and solvent-free condition. Through the study of kinetics, isotope labeling experiment and DFT calculation, it was found that in situ formed N-formyl quasi-catalytic species afford highly selective synthesis of formamides or amines with controllable levels from a variety of aldehyde- and ketone-derived platform chemical substrates (the reaction time can be as short as 3 min). Related results were published: Li, H, <strong>Fang, Z.*<\/strong> et al., Nat Commun, 2019, 10, 699; Li, H, <strong>Fang, Z.*<\/strong> et al., Green Chem, 2020, 22, 582.\uff09<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">2.Synthesized nanocatalysts to catalyze the high yield production of liquid biofuels and chemicals (e.g., methyl levulinate, \u03b3-valerolactone, 2,5-dimethylfuran, methylfuran, formamides) at low temperatures directly from carbohydrates (e.g., sugars, cellulose). It is found that 95% 2,5-dimethylfuran yield was obtained from fructose at 110 <sup>o<\/sup>C, 99% 2,5-dimethylfuran yield from 5-hydroxymethylfurfural and 97% 2-methylfuran yield from furfural were even achieved at room temperature (25 <sup>o<\/sup>C) when polymethylhydrosiloxane was used as H-donor. Therefore, liquid biofuels (e.g., 2,5-dimethylfuran) can be produced from sugars via the hydrolysis of lignocellulosic biomass that is easy for commercial applications in simple and inexpensive reactors.<\/p>\n<p style=\"text-align: justify;\">1)Construction of acid-base bifunctional materials and synergistic catalytic mechanism<\/p>\n<p style=\"text-align: justify;\">Integration of acidic and basic sites is difficult to be compatible in the conventional system into organic-inorganic porous materials through the solvent-thermal self-assembly method to construct an acid-base bifunctional nano-solid material. The bifunctional materials show excellent catalytic activity in the process of acid-base domino\/cascade- reaction (hydrogenation-lactonization, sugar isomerization-dehydration reaction) and multivariate reaction (simultaneous esterification-transesterification reaction). It can greatly simplify the reaction process without additional intermediate product separation process.<\/p>\n<p style=\"text-align: justify;\">Related results were published: Li, H, <strong>Fang, Z.*<\/strong> et al., Appl Catal B, 2018, 227, 79; Li, H, <strong>Fang, Z.*<\/strong> et al., ChemSusChem, 2017, 10, 681; Li, H, <strong>Fang, Z.*<\/strong> et al., Appl Catal B, 2017, 200, 182.\uff09<\/p>\n<p style=\"text-align: justify;\">2)Controllable C-C bond coupling technology is the basis for achieving biomass to long-chain alkanes. Aldol reaction is important carbon chain growth reaction in organic synthesis and is often used to structure C-C bonds. By using hydrotalcite-like nanomaterials as precursors, ZnAlLa composite alkaline oxide materials were prepared. Compared with traditional oxides (such as ZnO, ZrO<sub>2<\/sub>), the materials can efficiently catalyze the condensation reaction, and the conversion rate of furfural is much higher than that by La<sub>2<\/sub>O<sub>3<\/sub>. Characterization analysis was found that the excellent performance can be attributed to the structure of La<sub>2<\/sub>O<sub>2<\/sub>CO<sub>3<\/sub> in the ZnAlLa catalyst and the formation of a large number of La<sup>3+<\/sup>-O<sup>2-<\/sup> sites.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">3.Invented a \u2018fast hydrolysis\u2019 process (US patent: 8268126;9115215;9243303;3 CN patent). Wood can be completely dissolved upon fast-heating (7~16 <sup>o<\/sup>C\/s) to form a \u2018wood solution\u2019 at 329-367 <sup>o<\/sup>C at short reaction time (0.7-2 s) by adding Na<sub>2<\/sub>CO<sub>3<\/sub> in water. The \u2018wood solution\u2019 like liquid petroleum can be rapidly (ca. 15 s) hydrolyzed to sugars\/sugar oligomers in a liquid phase for subsequent biofuel production (e.g., ethanol) in a flow system. The invention opens the door, for the first time, to the possibility of developing industrial-scale technology at competitive cost for producing biofuels from lignocelluloses based on the \u2018fast hydrolysis\u2019 process continuously.<\/p>\n<p style=\"text-align: justify;\">Clarified the reason why lignocellulosic biomass (such as wood) is completely dissolved in subcritical water (<strong>Fang Z.*<\/strong>, AIChE J, 54, 2751, 2008).<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">4.Developed a green process for the production of biodiesel using magnetic solid catalysts instead of conventional liquid catalysts that are unrecoverable. The solid catalysts can be easily separated magnetically for recycles and successfully used for <em>Jatropha<\/em> biodiesel production. Microwave and ultrasound techniques were also introduced to promote biodiesel production. Our group built up a patented pilot flow reactor for continuous production of biodiesel with the solid catalysts (3-5 t\/day, patent license was transferred to a company). (4 CN patent; 20 papers in App Energy, Green Chem, Appl Catal B, Chem Eng J, Energ Convers Manage)<\/p>\n<p style=\"text-align: justify;\">Verified the mechanism of solid alkali catalysts (such as sodium silicate, sodium aluminosilicate, etc.) and microwave and ultrasonic technology that hindered the saponification reaction of free fatty acids and alkalis, catalyzing the production of biodiesel from high acid value waste oil (Related results were published: Zhang F, <strong>Fang, Z.*<\/strong> et al., Green Chem, 2016, 18, 3302; Zhang F, <strong>Fang, Z.*<\/strong> et al., Energy Convers Manag, 2017, 142, 107; Cong WJ, <strong>Fang, Z.*<\/strong> et al., Appl Energy, 2020, 264, 114735).<\/p>\n<p style=\"text-align: justify;\">Explained that by introducing Lewis \/ Bronsted acid and basic sites, the catalyst has two catalytic active centers at the same time, which can simultaneously catalyze the esterification and transesterification of free fatty acids and triglycerides in high acid value oils to synthesize biodiesel. The process can reduce the reaction steps, reduce energy loss and pollution, and greatly improve the conversion efficiency of high-acid-value oils to produce biodiesel (Related results were published: Wang YT, <strong>Fang, Z.*<\/strong> et al., Appl Energy, 2017, 204, 702; Wang YT, <strong>Fang, Z.*<\/strong> et al., Chem Eng J, 2018, 348, 929.).<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">5.Production of aromatic nitrile by pyrolysis of waste polyester plastic with ammonia and its reaction mechanism<\/p>\n<p style=\"text-align: justify;\">Aromatic nitrile is a kind of important industrial raw material, which are widely employed for medicine, polymer and functional material. Reasonable and value-added utilization of waste polyester plastics is very important. We have developed a method of catalytic pyrolysis with ammonia atmosphere to achieve the selective production of terephthalonitrile and benzonitrile from waste polyester plastics, and high purity of aromatic nitriles, and clarified the degradation paths of polyester plastics, and aromatic nitrile C-N bond construction mechanism. Related results were published: Xu L, <strong>Fang, Z.*<\/strong> et al., Waste Manag, 2019, 92, 97; Xu, <strong>Fang, Z.*<\/strong> et al., Catalysts, 2019, 9, 436.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">6.Organic solvent-Lewis acid pretreatment technology was established for the deconstruction and selective separation of lignocellulosic components from agricultural waste straw. The technology realizes the selective separation of a large amount of hemicellulose and lignin without losing cellulose under mild conditions. The mechanism of depolymerization and separation of lignin-carbohydrate complex in biomass, especially the change of lignin macromolecule during pretreatment, was elucidated by the multi-scale characterization of lignocellulosic structure. It provides a theoretical basis for the subsequent lignin recovery and utilization. Related results were published: Tang, S, <strong>Fang, Z.*<\/strong> et al., Bioresour Technol, 2019, 294, 122164; Tang, S, <strong>Fang, Z.*<\/strong> et al., Bioresour Technol, 2019, 284, 98.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">7.Regarding the catalytic conversion of lignocellulosic waste into hydrogen fuel, the following theoretical studies have been carried out. As a green fuel, hydrogen not only has high specific heating value and zero pollution advantages, but also can be converted into a variety of fuels and chemicals. We use modified 10Ni \/ Al<sub>2<\/sub>O<sub>3<\/sub> catalysts with different Co loadings to catalyze the hydrothermal gasification of lignocellulosic waste to produce hydrogen, which improved the hydrogen yield and realized the utilization of lignocellulosic waste. Related results were published: Sun, J, <strong>Fang, Z.*<\/strong> et al., J Supercrit Fluids, <strong>162<\/strong>, 104863<em>, <\/em><strong>2020<\/strong>. The reason for high gasification rate is clarified: sub\/supercritical water has low dielectric constant and large ion product, which is conducive to the dissolution and hydrolysis of lignocelluloses in water, and the low viscosity and large diffusion coefficient are conducive to the acceleration of mass transfer rate, thereby promoting chemical reaction. It catalyzed the hydrothermal gasification of cotton straw to produce H<sub>2<\/sub> with 82.6% yield by synthesized Co-Ni \/ Al<sub>2<\/sub>O<sub>3<\/sub> catalyst. This is due to the formation of Ni-Co alloy in the Co-Ni \/ Al<sub>2<\/sub>O<sub>3<\/sub> catalyst, which improves the gasification performance of the catalyst and enhances the ability of the catalyst to resist carbon deposition, avoiding the rapid deactivation of the catalyst caused by carbon deposition in catalyst.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">8.As editor-in-chief, Springer Book Series \u2013 Biofuels and Biorefineries (<a href=\"https:\/\/www.springer.com\/series\/11687\">https:\/\/www.springer.com\/series\/11687<\/a>), <strong>Prof. Fang<\/strong> leads editorial board composed of eight world-leaders in biofuels and biorefineries (2 NAE members, 4 FCAE, 1 FRS and a famous professor at Tohoku university in Japan). The purpose of this series is to organize bioenergy experts around the world to publish a series of books related to biomass in different fields, aimed at the publication of at least two volumes per year. The book series will be focusing on introducing knowledge, research and recent exhibitions all aspect related with biomass production, biofuels, bioproducts, chemicals, biomaterials, food and pharmaceutical products, energy planning and policy, as well as processing technologies. The book series will be the powerful and integrative source of biomass, bioenergy, biofuels, bioproducts and biorefinery for scientists, students, policy maker and engineers to reflect the explosive growth in this interdisciplinary area.<\/p>\n<p style=\"text-align: justify;\">At present, <strong>Prof. Fang<\/strong> has published 19 English books (12 Springer books with 350k chapter downloads). The series has published 10 monographs, with 170k chapter downloads, one book wins 2020 \u201c<a href=\"https:\/\/www.springernature.com\/gp\/researchers\/campaigns\/china-new-development-awards?gclid=EAIaIQobChMI49PMq_SX6wIVlpm9Ch0VuwaxEAEYASAAEgIJ7fD_BwE\">Springer-Nature China New Development Awards<\/a>\u201d in recognition of his exceptional contributions to the delivery of the UN Sustainable Development Goals (SDGs). Four books are among the \u201ctop 25% springer e-books\u201d.<\/p>\n<p style=\"text-align: justify;\">This book series has become the knowledge library of the latest progress and theoretical innovation of bioenergy studies and applications.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\"><strong>\u00a0<\/strong><\/p>\n<p style=\"text-align: justify;\"><strong>\u7406\u8bba\u521b\u65b0\uff1a<\/strong><\/p>\n<p style=\"text-align: justify;\">\u751f\u7269\u80fd\u6e90\u7ec4\u5728\u6728\u8d28\u7ea4\u7ef4\u7d20\u6c34\u89e3\u3001\u751f\u7269\u67f4\u6cb9\u5408\u6210\u3001\u6db2\u4f53\u751f\u7269\u71c3\u6599\u751f\u4ea7\u3001\u8d85\u4e34\u754c\u6d41\u4f53\u5de5\u827a\u3001\u50ac\u5316\u5242\u5408\u6210\u548c\u7eb3\u7c73\u6750\u6599\u7b49\u9886\u57df\u505a\u51fa\u4e86\u91cd\u5927\u8d21\u732e\u3002<\/p>\n<p style=\"text-align: justify;\"><strong>\u00a0<\/strong><\/p>\n<p style=\"text-align: justify;\">1.\u5f00\u521b\u4e86\u4ece\u78b3\u6c34\u5316\u5408\u7269\u4e2d\u4f4e\u6e29\u5408\u6210\u542b\u6c2e\u5316\u5408\u7269\u548c\u6db2\u4f53\u71c3\u6599 (Nat Commun; PCT\/CN2017\/106729, PCT\/CN2019\/098614, 2\u9879\u4e2d\u56fd\u4e13\u5229)\u3002\u65e0\u8bba\u6709\u6ca1\u6709\u7eb3\u7c73\u50ac\u5316\u5242\uff0c\u6728\u8d28\u7ea4\u7ef4\u7d20\u6c34\u89e3\u548c\u5206\u89e3\u540e\u51e0\u4e4e\u53ef\u4ee5\u5b8c\u5168\u8f6c\u5316\u4e3a\u4e9a\u80fa\u548c\u6db2\u4f53\u71c3\u6599(2,5-\u4e8c\u7532\u57fa\u544b\u5583\u3001\u4e59\u9170\u4e19\u9178\u7532\u916f\u3001\u03b3-\u620a\u5185\u916f\u3001\u7532\u57fa\u544b\u5583)\u3002<\/p>\n<p style=\"text-align: justify;\"><strong>N-<\/strong><strong>\u7532\u9170\u57fa\u51c6\u50ac\u5316\u7269\u79cd\u7684\u53d1\u73b0\u53ca\u53cd\u5e94\u673a\u5236<\/strong><strong>.<\/strong> \u4f2f\u80fa\u4f5c\u4e3a\u91cd\u8981\u7684\u5de5\u4e1a\u539f\u6599\uff0c\u5728\u836f\u7269\u3001\u805a\u5408\u7269\u3001\u529f\u80fd\u6750\u6599\u7b49\u65b9\u9762\u5177\u6709\u5e7f\u6cdb\u7684\u5e94\u7528\u4ef7\u503c\u3002\u901a\u5e38\uff0c\u4f2f\u80fa\u53ef\u901a\u8fc7\u91d1\u5c5e\u50ac \u5316\u8fd8\u539f\u80fa\u5316\u53cd\u5e94\u5236\u5907\u5f97\u5230\uff0c\u4f46\u5b58\u5728\u91d1\u5c5e\u50ac\u5316\u5242\u4ef7\u683c\u6602\u8d35\u3001\u5236\u5907\u8fc7\u7a0b\u8f83\u590d\u6742\u7b49\u95ee\u9898\u3002\u9488\u5bf9\u4e0a\u8ff0\u95ee\u9898\uff0c\u6211\u4eec\u5f00\u53d1\u4e86\u4e00 \u79cd\u5168\u65b0\u7684\u5728\u65e0\u50ac\u5316\u5242\u548c\u6eb6\u5242\u7684\u6761\u4ef6\u4e0b\u5408\u6210\u4f2f\u80fa\u7684\u7eff\u8272\u65b9\u6cd5\uff0c\u901a\u8fc7\u52a8\u529b\u5b66\u3001\u540c\u4f4d\u7d20\u6807\u8bb0\u5b9e\u9a8c\u4ee5\u53ca DFT\u8ba1\u7b97\u7b49\u7814\u7a76\u53d1 \u73b0\u539f\u4f4d\u5f62\u6210\u7684 N-\u7532\u9170\u57fa\u4f5c\u4e3a\u51c6\u50ac\u5316\u7269\u79cd\uff0c\u53ef\u4fc3\u8fdb\u5e76\u8c03\u63a7\u4e00\u7cfb\u5217\u751f\u7269\u8d28\u57fa\u919b\u548c\u916e\u5316\u5408\u7269\u9ad8\u9009\u62e9\u6027\u751a\u81f3\u5b9a\u91cf\u8f6c\u5316\u4e3a\u7532 \u9170\u80fa\u6216\u80fa(\u53cd\u5e94\u65f6\u95f4\u53ef\u77ed\u81f3 3 min)\u3002\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\u5728\uff1aLi, H, <strong>Fang, Z.*<\/strong> et al., Nat Commun, 2019, 10, 699; Li, H, <strong>Fang, Z.*<\/strong> et al., Green Chem, 2020, 22, 582. \uff09<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">2.\u5408\u6210\u7eb3\u7c73\u50ac\u5316\u5242\uff0c\u5728\u4f4e\u6e29\u6761\u4ef6\u4e0b\u76f4\u63a5\u50ac\u5316\u78b3\u6c34\u5316\u5408\u7269\uff08\u4f8b\u5982\u7cd6\uff0c\u7ea4\u7ef4\u7d20\uff09\u9ad8\u4ea7\u7387\u751f\u4ea7\u6db2\u4f53\u751f\u7269\u71c3\u6599\u548c\u5316\u5b66\u54c1\uff08\u4f8b\u5982\u4e59\u9170\u4e19\u9178\u7532\u916f\uff0c\u03b3-\u620a\u5185\u916f\uff0c2,5-\u4e8c\u7532\u57fa\u544b\u5583\uff0c\u7532\u57fa\u544b\u5583\uff09\u3002\u7814\u7a76\u53d1\u73b0\u5728110 <sup>o<\/sup>C\u6761\u4ef6\u4e0b\u679c\u7cd6\u4e2d\u83b7\u5f972,5-\u4e8c\u7532\u57fa\u544b\u5583\u7684\u4ea7\u7387\u4e3a95\uff05\uff0c\u5728\u5ba4\u6e29\u6761\u4ef6\uff0825 <sup>o<\/sup>C\uff09\uff0c\u4ee5\u805a\u7532\u57fa\u6c22\u7845\u6c27\u70f7\u4f5c\u4e3a\u6c22\u4f9b\u4f53\u65f6\uff0c\u53ef\u4ee5\u4ece5-\u7f9f\u7532\u57fa\u7ce0\u919b\u4e2d\u83b7\u5f9799\uff05\u76842,5-\u4e8c\u7532\u57fa\u544b\u5583\u4ea7\u7387\u548c\u7ce0\u919b\u4e2d97\uff05\u76842-\u7532\u57fa\u544b\u5583\u4ea7\u7387\u3002\u56e0\u6b64\uff0c\u53ef\u4ee5\u901a\u8fc7\u6728\u8d28\u7ea4\u7ef4\u7d20\u7684\u6c34\u89e3\u7cd6\u751f\u4ea7\u6db2\u4f53\u751f\u7269\u71c3\u6599\uff08\u4f8b\u59822,5-\u4e8c\u7532\u57fa\u544b\u5583\uff09\uff0c\u8fd9\u65b9\u6cd5\u6613\u4e8e\u5728\u7b80\u5355\u4e14\u5ec9\u4ef7\u7684\u53cd\u5e94\u5668\u4e2d\u8fdb\u884c\u5546\u4e1a\u5e94\u7528\u3002<\/p>\n<p style=\"text-align: justify;\"><strong>\u9178<\/strong><strong>&#8211;<\/strong><strong>\u78b1\u53cc\u529f\u80fd\u6750\u6599\u7684\u6784\u7b51\u53ca\u5176\u534f\u540c\u50ac\u5316\u673a\u5236<\/strong><strong>. <\/strong>\u5c06\u5e38\u89c4\u4f53\u7cfb\u4e2d\u96be\u517c\u5bb9\u7684\u9178\u6027\u548c\u78b1\u6027\u4f4d\u70b9\uff0c\u901a\u8fc7\u7814\u53d1\u7684\u70ed\u6db2\u81ea\u7ec4\u88c5\u624b\u6bb5\uff0c\u6574\u5408\u5230\u6709\u673a-\u65e0\u673a\u591a\u5b54\u6750\u6599\u4e0a\uff0c\u6784\u7b51\u51fa\u517c\u5177\u9178-\u78b1\u4f4d\u70b9\u7684\u53cc\u529f\u80fd\u7eb3\u7c73\u56fa\u4f53\u6750\u6599\uff1b\u8be5\u7c7b\u53cc\u529f\u80fd\u6750\u6599\u5728\u9178-\u78b1\u7ea7\u8054\u53cd\u5e94(\u6c22\u5316-\u5185\u916f\u5316\u3001\u7cd6\u5f02\u6784\u5316-\u8131\u6c34\u53cd\u5e94\u7b49)\u548c\u591a\u5143\u53cd\u5e94(\u540c\u65f6\u916f\u5316-\u916f\u4ea4\u6362\u53cd\u5e94\u7b49)\u8fc7\u7a0b\u4e2d\uff0c\u8868\u73b0\u51fa\u4f18\u5f02\u7684\u50ac\u5316\u6d3b\u6027\uff0c\u4e14\u53ef\u5927\u5927\u7b80\u5316\u53cd\u5e94\u5de5\u827a\u3001\u65e0\u9700\u989d\u5916\u4e2d\u95f4\u4ea7\u7269\u5206\u79bb\u8fc7\u7a0b\u7b49\u3002\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\u5728\uff1aLi, H, <strong>Fang, Z.*<\/strong> et al., Appl Catal B, 2018, 227, 79; Li, H, <strong>Fang, Z.*<\/strong> et al., ChemSusChem, 2017, 10, 681; Li, H, <strong>Fang, Z.*<\/strong> et al., Appl Catal B, 2017, 200, 182.\uff09\u3002<\/p>\n<p style=\"text-align: justify;\"><strong>\u53ef\u63a7\u7684<\/strong><strong>C-C<\/strong><strong>\u952e\u5076\u8054\u6280\u672f\u662f\u5b9e\u73b0\u751f\u7269\u8d28\u5230\u957f\u94fe\u70f7\u70c3\u7684\u57fa\u7840<\/strong>. \u7f9f\u919b\u7f29\u5408\u662f\u6709\u673a\u5408\u6210\u4e2d\u91cd\u8981\u7684\u78b3\u94fe\u589e\u957f\u53cd\u5e94\uff0c\u5e38\u7528\u4e8e\u67b6\u6784C-C\u952e\u3002\u901a\u8fc7\u4ee5\u7c7b\u6c34\u6ed1\u77f3\u7eb3\u7c73\u6750\u6599\u4e3a\u524d\u9a71\u4f53\uff0c\u5236\u5907ZnAlLa\u590d\u5408\u78b1\u6027\u6c27\u5316\u7269\u6750\u6599\uff0c\u8be5\u6750\u6599\u76f8\u8f83\u4e8e\u4f20\u7edf\u7684\u6c27\u5316\u7269\uff08\u5982ZnO\uff0cZrO<sub>2<\/sub>\u7b49\uff09\u80fd\u591f\u9ad8\u6548\u50ac\u5316\u7f29\u5408\u53cd\u5e94\uff0c\u5e76\u4e14\u7ce0\u919b\u8f6c\u5316\u901f\u7387\u8fdc\u9ad8\u4e8eLa<sub>2<\/sub>O<sub>3<\/sub>\u3002\u901a\u8fc7\u8868\u5f81\u5206\u6790\u53d1\u73b0\uff0c\u4f18\u5f02\u7684\u6027\u80fd\u53ef\u5f52\u56e0\u4e8eZnAlLa\u50ac\u5316\u5242\u4e2dLa<sub>2<\/sub>O<sub>2<\/sub>CO<sub>3<\/sub>\u7ed3\u6784\u4ee5\u53ca\u5927\u91cfLa<sup>3+<\/sup>-O<sup>2-<\/sup>\u4f4d\u70b9\u7684\u5f62\u6210\u3002<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">3.\u53d1\u660e\u201c\u5feb\u901f\u6c34\u89e3\u201d\u6280\u672f (\u7f8e\u56fd\u4e13\u5229\u53f7:8268126;9115215;9243303;3 CN\u4e13\u5229)\u3002\u5728\u6c34\u4e2d\u6dfb\u52a0Na<sub>2<\/sub>CO<sub>3<\/sub>\u5230\u6728\u6750\u751f\u7269\u8d28\u9897\u7c92\uff08\u6216\u6728\u8d28\u7ea4\u7ef4\u7d20\u751f\u7269\u8d28\uff09\u4e2d\uff0c\u6728\u6750\u518d\u5feb\u901f\u5347\u6e29(7~16 <sup>o<\/sup>C\/s)\u81f3329-367 <sup>o<\/sup>C\u4e0b\uff0c\u53ef\u57280.7~2 s\u5185\u5b8c\u5168\u6eb6\u89e3\u5f62\u6210\u201c\u6728\u6750\u6eb6\u6db2\u201d\u3002\u5728\u6d41\u52a8\u7cfb\u7edf\u4e2d\uff0c\u7c7b\u4f3c\u4e8e\u6db2\u6001\u77f3\u6cb9\u7684\u201c\u6728\u6db2\u201d\u53ef\u4ee5\u5728\u6db2\u76f8\u4e2d\u5feb\u901f\u6c34\u89e3\u6210\u7cd6\/\u7cd6\u4f4e\u805a\u7269\uff0c\u7528\u4e8e\u968f\u540e\u751f\u7269\u71c3\u6599\u7684\u751f\u4ea7(\u5982\u4e59\u9187)\u3002\u6b64\u53d1\u660e\u7b2c\u4e00\u6b21\u6253\u5f00\u4e86\uff0c\u5177\u6709\u7ade\u4e89\u529b\u7684\u6210\u672c\u5f00\u53d1\u5de5\u4e1a\u89c4\u6a21\uff0c \u57fa\u4e8e\u201c\u5feb\u901f\u6c34\u89e3\u201d\u8fc7\u7a0b\u8fde\u7eed\u5730\u4ece\u6728\u8d28\u7ea4\u7ef4\u7d20\uff0c\u751f\u4ea7\u751f\u7269\u71c3\u6599\u53ef\u80fd\u6027\u3002<\/p>\n<p style=\"text-align: justify;\">\u9610\u660e\u4e86\u6728\u8d28\u7ea4\u7ef4\u7d20\u751f\u7269\u8d28\uff08\u5982\u6728\u6750\uff09\u5728\u4e9a\u4e34\u754c\u6c34\u5b8c\u5168\u6eb6\u89e3\u7684\u539f\u56e0\uff08<strong>Fang Z.*<\/strong>, AIChE J, 54, 2751, 2008).\uff09\u3002<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">4.\u5f00\u53d1\u4e86\u51fa\u7eff\u8272\u5de5\u827a\uff0c\u4f7f\u7528\u78c1\u6027\u56fa\u4f53\u50ac\u5316\u5242\u4ee3\u66ff\u65e0\u6cd5\u56de\u6536\u7684\u5e38\u89c4\u6db2\u4f53\u50ac\u5316\u5242\u751f\u4ea7\u751f\u7269\u67f4\u6cb9\u3002\u56fa\u4f53\u50ac\u5316\u5242\u53ef\u4ee5\u5f88\u5bb9\u6613\u5730\u901a\u8fc7\u78c1\u529b\u5206\u79bb\u8fdb\u884c\u518d\u5faa\u73af\uff0c\u5e76\u6210\u529f\u7528\u4e8e\u5c0f\u6850\u5b50\u751f\u7269\u67f4\u6cb9\u7684\u751f\u4ea7\u3002\u5e76\u4e14\u5f15\u5165\u4e86\u5fae\u6ce2\u548c\u8d85\u58f0\u6280\u672f\u6765\u63d0\u5347\u751f\u7269\u67f4\u6cb9\u7684\u751f\u4ea7\u3002\u56e2\u961f\u53d1\u660e\u4e86\u4e00\u79cd\u4e2d\u8bd5\u6d41\u52a8\u53cd\u5e94\u5668\uff0c\u5229\u7528\u56fa\u4f53\u50ac\u5316\u5242\u8fde\u7eed\u751f\u4ea7\u751f\u7269\u67f4\u6cb9\uff083-5\u5428\/\u5929\uff0c\u8be5\u8bbe\u5907\u4e13\u5229\u5df2\u8f6c\u8ba9\u7ed9\u516c\u53f8\uff09\u3002(4\u9879\u4e2d\u56fd\u4e13\u5229; 20 papers in App Energy, Green Chem, Appl Catal B, Chem Eng J, Energ Convers Manage).<\/p>\n<p style=\"text-align: justify;\">\u9610\u660e\u56fa\u4f53\u78b1\u50ac\u5316\u5242\uff08\u5982\uff1a\u7845\u9178\u94a0\u3001\u7845\u94dd\u9178\u94a0\u7b49\uff09\u4ee5\u53ca\u5fae\u6ce2\u548c\u8d85\u58f0\u6280\u672f\u963b\u788d\u81ea\u7531\u8102\u80aa\u9178\u4e0e\u78b1\u53d1\u751f\u7682\u5316\u53cd\u5e94\u7684\uff0c\u50ac\u5316\u9ad8\u9178\u503c\u5e9f\u5f03\u6cb9\u8102\u5236\u5907\u751f\u7269\u67f4\u6cb9\u7684\u673a\u5236\uff08\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\uff1aZhang F, <strong>Fang, Z.*<\/strong> et al., Green Chem, 2016, 18, 3302; Zhang F, <strong>Fang, Z.*<\/strong> et al., Energy Convers Manag, 2017, 142, 107; Cong WJ, <strong>Fang, Z.*<\/strong> et al., Appl Energy, 2020, 264, 114735\uff09\u3002\u89e3\u91ca\u4e86\u901a\u8fc7\u5f15\u5165Lewis\/Bronsted \u9178\u548c\u78b1\u6027\u4f4d\u70b9\uff0c\u4f7f\u50ac\u5316\u5242\u540c\u65f6\u5177\u5907\u4e24\u79cd\u50ac\u5316\u6d3b\u6027\u4e2d\u5fc3\uff0c\u53ef\u540c\u65f6\u50ac\u5316\u9ad8\u9178\u503c\u6cb9\u8102\u4e2d\u7684\u81ea\u7531\u8102\u80aa\u9178\u548c\u7518\u6cb9\u4e09\u916f\u53d1\u751f\u916f\u5316\u548c\u8f6c\u916f\u5316\u53cd\u5e94\u5408\u6210\u751f\u7269\u67f4\u6cb9\uff0c\u8be5\u5de5\u827a\u53ef\u7f29\u51cf\u53cd\u5e94\u6b65\u9aa4\u3001\u51cf\u5c11\u80fd\u91cf\u635f\u8017\u548c\u6c61\u67d3\u3001\u5927\u5927\u63d0\u9ad8\u4e86\u9ad8\u9178\u503c\u6cb9\u8102\u5236\u5907\u751f\u7269\u67f4\u6cb9\u7684\u8f6c\u5316\u6548\u7387\uff08\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\uff1aWang YT, <strong>Fang, Z.*<\/strong> et al., Appl Energy, 2017, 204, 702; Wang YT, <strong>Fang, Z.*<\/strong> et al., Chem Eng J, 2018, 348, 929.\uff09<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\"><strong>5.<\/strong><strong>\u5e9f\u5f03\u805a\u916f\u5851\u6599\u70ed\u89e3\u6c28\u5316\u8d44\u6e90\u5316\u5236\u5907\u82b3\u9999\u8148\u53ca\u5176\u53cd\u5e94\u673a\u5236<\/strong><strong>.<\/strong> \u82b3\u9999\u8148\u662f\u4e00\u7c7b\u91cd\u8981\u7684\u5de5\u4e1a\u539f\u6599\uff0c\u5728\u836f\u7269\u3001\u805a\u5408\u7269\u3001\u529f\u80fd\u6750\u6599\u7b49\u65b9\u9762\u5177\u6709\u5e7f\u6cdb\u7684\u5e94\u7528\u4ef7\u503c\u3002\u5e9f\u5f03\u805a\u916f\u5851\u6599\u662f\u76ee\u524d\u751f\u6d3b\u4e2d\u5927\u5b97\u7684\u5e9f\u5f03\u5851\u6599\uff0c\u5bf9\u5176\u5408\u7406\u548c\u589e\u503c\u5316\u5229\u7528\u975e\u5e38\u91cd\u8981\u3002\u6211\u4eec\u5f00\u53d1\u4e86\u901a\u8fc7\u6c28\u6c14\u6c1b\u56f4\u50ac\u5316\u70ed\u89e3\u7684\u65b9\u6cd5\u5b9e\u73b0\u5e9f\u5f03\u805a\u916f\u5851\u6599\u9009\u62e9\u6027\u5236\u5907\u5bf9\u82ef\u4e8c\u7532\u8148\u548c\u82ef\u7532\u8148\u4e24\u79cd\u5316\u5b66\u54c1\uff0c\u5e76\u53ef\u4ee5\u5b9e\u73b0\u82b3\u9999\u8148\u7684\u9ad8\u7eaf\u5ea6\u63d0\u7eaf\u548c\u660e\u786e\u805a\u916f\u5851\u6599\u964d\u89e3\u9014\u5f84\u548c\u82b3\u9999\u8148 C-N\u952e\u6784\u7b51\u673a\u5236\uff0c\u4e3a\u5b9e\u73b0\u5e9f\u5f03\u5316\u5408\u7269\u7684\u9ad8\u9644\u52a0\u503c\u8d44\u6e90\u5316\u5229\u7528\u548c\u82b3\u9999\u775b\u5316\u5b66\u54c1\u7684\u7eff\u8272\u751f\u4ea7\u7684\u63d0\u4f9b\u4e00\u6761\u53ef\u80fd\u7684 \u53cd\u5e94\u9014\u5f84\u3002\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\u5728\uff1aXu L, <strong>Fang, Z.*<\/strong> et al., Waste Manag, 2019, 92, 97; Xu, <strong>Fang, Z.*<\/strong> et al., Catalysts, 2019, 9, 436.<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">6.\u4ee5\u519c\u4e1a\u5e9f\u5f03\u79f8\u79c6\u4e3a\u539f\u6599\uff0c\u9488\u5bf9\u6728\u8d28\u7ea4\u7ef4\u7d20\u89e3\u6784\u53ca\u7ec4\u5206\u9009\u62e9\u6027\u5206\u79bb\uff0c\u6211\u4eec\u5efa\u7acb\u4e86\u6709\u673a\u6eb6\u5242-\u8def\u6613\u65af\u9178\u9884\u5904\u7406\u6280\u672f\u3002\u8be5 \u6280\u672f\u5b9e\u73b0\u5728\u4e86\u6e29\u548c\u6761\u4ef6\u4e0b\uff0c\u4e0d\u635f\u5931\u7ea4\u7ef4\u7d20\u7684\u540c\u65f6\uff0c\u9009\u62e9\u6027\u5206\u79bb\u51fa\u5927\u91cf\u534a\u7ea4\u7ef4\u7d20\u548c\u6728\u8d28\u7d20\u3002\u5e76\u901a\u8fc7\u6728\u8d28\u7ea4\u7ef4\u7d20\u7ed3\u6784 \u4e0a\u591a\u5c3a\u5ea6\u8868\u5f81\uff0c\u9610\u660e\u4e86\u751f\u7269\u8d28\u4e2d\u6728\u8d28\u7d20-\u78b3\u6c34\u5316\u5408\u7269\u590d\u5408\u7269\u7684\u89e3\u805a\u5206\u79bb\u673a\u5236\uff0c\u5c24\u5176\u662f\u9884\u5904\u7406\u8fc7\u7a0b\u4e2d\u6728\u8d28\u7d20\u5927\u5206\u5b50\u7684 \u53d8\u5316\uff0c\u4e3a\u540e\u7eed\u6728\u7d20\u56de\u6536\u5229\u7528\u63d0\u4f9b\u4e86\u7406\u8bba\u57fa\u7840\u3002\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\u5728\uff1aTang, S, <strong>Fang, Z.*<\/strong> et al., Bioresour Technol, 2019, 294, 122164; Tang, S, <strong>Fang, Z.*<\/strong> et al., Bioresour Technol, 2019,\u00a0 284, 98\u3002<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">7.\u56f4\u7ed5\u6728\u8d28\u7ea4\u7ef4\u7d20\u5e9f\u5f03\u7269\u50ac\u5316\u8f6c\u5316\u4e3a\u6c22\u6c14\u71c3\u6599\uff0c\u5f00\u5c55\u4e86\u5982\u4e0b\u7406\u8bba\u7814\u7a76\uff1a\u6c22\u6c14\u4f5c\u4e3a\u4e00\u79cd\u7eff\u8272\u71c3\u6599\uff0c \u4e0d\u4ec5\u5177\u6709\u9ad8\u7684\u6bd4\u70ed\u503c\u548c\u96f6\u6c61\u67d3\u4f18\u70b9\uff0c\u8fd8\u53ef\u4ee5\u8f6c\u5316\u4e3a\u591a\u79cd\u71c3\u6599\u548c\u5316\u5b66\u54c1\u3002\u6211\u4eec\u5229\u7528\u4e0d\u540c Co\u8d1f\u8f7d\u91cf\u6539 \u6027 10Ni\/Al<sub>2<\/sub>O<sub>3<\/sub>\u50ac\u5316\u5242\uff0c\u7528\u4e8e\u50ac\u5316\u6728\u8d28\u7ea4\u7ef4\u7d20\u5e9f\u5f03\u7269\u6c34\u70ed\u6c14\u5316\u5236\u53d6\u6c22\u6c14\uff0c\u4e0d\u4ec5\u63d0\u9ad8\u4e86\u6c22\u6c14\u4ea7\u7387\u8fd8\u5b9e\u73b0 \u6728\u8d28\u7ea4\u7ef4\u7d20\u5e9f\u5f03\u7269\u7684\u8d44\u6e90\u5316\u5229\u7528\u3002\u76f8\u5173\u5de5\u4f5c\u53d1\u8868\uff1aSun, J, <strong>Fang, Z.*<\/strong> et al., J Supercrit Fluids , <strong>162<\/strong>, 104863<em>, <\/em><strong>2020<\/strong>.<\/p>\n<p style=\"text-align: justify;\">\u9610\u660e\u4e86\u9ad8\u6c14\u5316\u7387\u7684\u539f\u56e0: \u4e9a\/\u8d85\u4e34\u754c\u6c34\u5177\u6709\u4f4e\u7684\u4ecb\u7535\u5e38\u6570\u548c\u5927\u7684\u79bb\u5b50\u79ef\u8fd9\u6709\u5229\u4e8e\u6728\u8d28\u7ea4\u7ef4\u7d20\u5e9f\u5f03\u7269\u5728\u6c34\u4e2d\u8fdb\u884c\u6eb6\u89e3\u548c\u6c34\u89e3\uff0c\u4e14\u4f4e\u7684\u7c98\u5ea6\u548c\u5927\u7684\u6269\u6563\u7cfb\u6570\u6709\u5229\u4e8e\u52a0\u5feb\u4f20\u8d28\u901f\u7387\uff0c\u4ece\u800c\u4fc3\u8fdb\u5316\u5b66\u53cd\u5e94\u3002\u6240\u5408\u6210\u7684Co-Ni\/Al<sub>2<\/sub>O<sub>3<\/sub>\u50ac\u5316\u5242\u50ac\u5316\u68c9\u82b1\u79f8\u79c6\u6c34\u70ed\u6c14\u5316\u7684H<sub>2<\/sub>\u4ea7\u7387\u53ef\u4ee5\u8fbe\u523082.6%\u8fd9\u662f\u7531\u4e8eCo-Ni\/Al<sub>2<\/sub>O<sub>3<\/sub>\u50ac\u5316\u5242\u4e2d\u5f62\u6210\u4e86Ni-Co\u5408\u91d1\uff0c\u63d0\u9ad8\u4e86\u50ac\u5316\u5242\u7684\u6c14\u5316\u6027\u80fd\uff0c\u4e14\u589e\u5f3a\u4e86\u50ac\u5316\u5242\u6297\u79ef\u78b3\u7684\u80fd\u529b\uff0c\u907f\u514d\u4e86\u50ac\u5316\u5242\u5728\u53cd\u5e94\u4e2d\u56e0\u79ef\u78b3\u5f15\u8d77\u7684\u5feb\u901f\u5931\u6d3b\u3002<\/p>\n<p style=\"text-align: justify;\">\n<p style=\"text-align: justify;\">8.\u519c\u6797\u5e9f\u5f03\u751f\u7269\u8d28\u8d44\u6e90\u5316\u4e0d\u4ec5\u53ef\u4ee5\u51cf\u5c11\u5e9f\u5f03\u7269\u5bf9\u73af\u5883\u7684\u6c61\u67d3\u800c\u4e14\u662f\u6211\u56fd\u6539\u5584\u80fd\u6e90\u7ed3\u6784\u7684\u73b0\u5b9e\u9700\u6c42\u3002\u751f\u7269\u8d28\u9884\u5904\u7406\u662f\u6728\u8d28\u7ea4\u7ef4\u751f\u7269\u8d28\u751f\u7269\u70bc\u5236\u7684\u7b2c\u4e00\u6b65\uff0c\u76f4\u63a5\u51b3\u5b9a\u4e86\u540e\u7eed\u70bc\u5236\u8fc7\u7a0b\u7684\u6548\u7387\u548c\u4ea7\u91cf\u3002\u5728\u4ee5\u4e8c\u5143\u9187\u4e3a\u6eb6\u5242\u7684\u751f\u7269\u8d28\u9884\u5904\u7406\u8fc7\u7a0b\u4e2d\uff0c\u4e8c\u5143\u9187\u5728\u6728\u8d28\u7d20a\u4f4d\u7684\u919a\u5316\u53cd\u5e94\u4e3a\u6728\u8d28\u7d20\u5f15\u5165\u201c\u7f9f\u57fa\u5c3e\u5df4\u201d\u3002\u867d\u7136a\u4f4d\u7684\u919a\u5316\u53cd\u5e94\u5df2\u88ab\u8bc1\u5b9e\u53ef\u4ee5\u6291\u5236\u6728\u8d28\u7d20\u7684\u7f29\u5408\uff0c\u4f46\u662f\u7531\u4e8e\u5176\u4e0e\u6728\u8d28\u7d20\u7684\u89e3\u805a\u53cd\u5e94\u662f\u7ade\u4e89\u53cd\u5e94\uff0c\u5728\u6709\u673a\u6eb6\u5242\u9884\u5904\u7406\u7684\u8fc7\u7a0b\u4e2d\u4f1a\u964d\u4f4e\u6728\u8d28\u7d20\u7684\u5206\u79bb\u6548\u7387\u3002\u6211\u4eec\u7814\u7a76\u53d1\u73b0\u4e8c\u5143\u9187\u9884\u5904\u7406\u5f15\u5165\u7684\u201c\u7f9f\u57fa\u5c3e\u5df4\u201d\u76f4\u63a5\u589e\u52a0\u6728\u8d28\u7d20\u4e0e\u4e8c\u5143\u9187\u6c22\u952e\u6eb6\u5242\u53c2\u6570\u7684\u76f8\u4f3c\u5ea6\uff0c\u4e0d\u4ec5\u53ef\u4ee5\u6291\u5236\u9884\u5904\u7406\u8fc7\u7a0b\u4e2d\u6728\u8d28\u7d20\u7684\u7f29\u5408\uff0c\u8fd8\u53ef\u4ee5\u63d0\u9ad8\u6728\u8d28\u7d20\u7684\u6eb6\u89e3\u5ea6\uff0c\u4f7f\u6728\u8d28\u7d20\u7684\u6eb6\u51fa\u7387\u63d0\u9ad810%\uff0c\u7ed3\u6784\u5b8c\u6574\u5ea6\u63d0\u9ad820%\u3002<\/p>\n<p style=\"text-align: justify;\">9.\u65b9\u8001\u5e08\u4f5c\u4e3aSpringer\u7cfb\u5217\u4e1b\u4e66<strong>\u201c\u751f\u7269\u71c3\u6599\u548c\u751f\u7269\u70bc\u5236\u201d<\/strong>\u00a0\u521b\u59cb\u603b\u7f16\u8f91\uff0c\u4ed6\u8d1f\u8d23\u7684\u7f16\u59d4\u4f1a\uff0c\u7531\u516b\u4f4d\u4e16\u754c\u8457\u540d\u7684\u751f\u7269\u71c3\u6599\u548c\u751f\u7269\u70bc\u5236\u4e13\u5bb6\u7ec4\u6210\uff08\u4e24\u4f4d\u7f8e\u56fd\u5de5\u7a0b\u9662\u9662\u58eb\uff0c\u56db\u4f4d\u52a0\u62ff\u5927\u5de5\u7a0b\u9662\u9662\u58eb\uff0c\u4e00\u4f4d\u52a0\u62ff\u5927\u7687\u5bb6\u5b66\u4f1a\u9662\u58eb\u548c\u4e00\u4f4d\u65e5\u672c\u4e1c\u5317\u5927\u5b66\u8457\u540d\u6559\u6388\uff09\u3002\u8be5\u7cfb\u5217\u4e1b\u4e66\u7684\u76ee\u7684\u662f\u7ec4\u7ec7\u4e16\u754c\u5404\u5730\u7684\u751f\u7269\u80fd\u6e90\u4e13\u5bb6\u51fa\u7248\u4e00\u7cfb\u5217\u5728\u4e0d\u540c\u9886\u57df\u4e0e\u751f\u7269\u8d28\u76f8\u5173\u7684\u4e66\u7c4d\uff0c\u65e8\u5728\u6bcf\u5e74\u81f3\u5c11\u51fa\u72481-2\u518c\u4e13\u8457\u3002\u8be5\u7cfb\u5217\u4e1b\u4e66\u5c06\u7740\u91cd\u4e8e\u4ecb\u7ecd\u4e0e\u751f\u7269\u8d28\u751f\u4ea7\uff0c\u751f\u7269\u71c3\u6599\uff0c\u751f\u7269\u5236\u54c1\uff0c\u5316\u5b66\u54c1\uff0c\u751f\u7269\u6750\u6599\uff0c\u98df\u54c1\u548c\u533b\u836f\u4ea7\u54c1\uff0c\u80fd\u6e90\u89c4\u5212\u548c\u653f\u7b56\uff0c\u4ee5\u53ca\u52a0\u5de5\u6280\u672f\u76f8\u5173\u7684\u6240\u6709\u65b9\u9762\u7684\u77e5\u8bc6\uff0c\u7814\u7a76\u548c\u8fd1\u5c55\u3002\u8be5\u7cfb\u5217\u4e1b\u4e66\u5c06\u662f\u5f3a\u5927\u7684\u548c\u7efc\u5408\u7684\u6709\u5173\u751f\u7269\u8d28\u751f\u4ea7\uff0c\u751f\u7269\u80fd\u6e90\uff0c\u751f\u7269\u71c3\u6599\uff0c\u751f\u7269\u5236\u54c1\u7684\u77e5\u8bc6\u5e93\u3002\u4e3a\u79d1\u5b66\u5bb6\uff0c\u5b66\u751f\uff0c\u653f\u7b56\u5236\u5b9a\u8005\u548c\u5de5\u7a0b\u5e08\u63d0\u4f9b\u77e5\u8bc6\u4ee5\u53cd\u6620\u751f\u7269\u70bc\u5236\u8fd9\u4e2a\u4ea4\u53c9\u5b66\u79d1\u9886\u57df\u7814\u7a76\u7684\u7206\u70b8\u6027\u589e\u957f\u5e76\u5f15\u5bfc\u8be5\u5b66\u79d1\u7684\u53d1\u5c55\u3002<\/p>\n<p style=\"text-align: justify;\">\u76ee\u524d\uff0c\u65b9\u8001\u5e08\u53d1\u8868\u82f1\u6587\u4e13\u845720\u90e8\uff08Springer 13\u90e8\uff0c38\u4e07\u6b21\u7ae0\u8282\u4e0b\u8f7d\u91cf\uff09\u3002\u8be5\u7cfb\u5217\u4e1b\u4e66\u51fa\u724810\u90e8\u4e13\u8457\uff0c\u7ae0\u8282\u7684\u8bb8\u591a\u4f5c\u8005\u6216\u5ba1\u7a3f\u4eba\u4e3a\uff08\u6216\u6210\u4e3a\uff09\u4e2d\u56fd\u548c\u53d1\u8fbe\u56fd\u5bb6\u9662\u58eb\u6216\u8457\u540d\u671f\u520a\u7684\u603b\u7f16\u8f91\uff0c\u7ae0\u8282\u4e0b\u8f7d\u91cf\uff08\u7535\u5b50\u7248\u9500\u552e\u91cf\uff0918\u4e07\u6b21\u3002\u5176\u4e2d\u4e00\u672c\u4e66\u8d62\u5f97\u4e862020\u5e74\u201c\u65af\u666e\u6797\u683c-\u81ea\u7136\u4e2d\u56fd\u65b0\u53d1\u5c55\u5956\u201d\uff0c\u4ee5\u8868\u5f70\u4ed6\u5bf9\u5b9e\u73b0\u8054\u5408\u56fd\u53ef\u6301\u7eed\u53d1\u5c55\u76ee\u6807\uff08SDGs\uff09\u7684\u6770\u51fa\u8d21\u732e\u3002\u4ed6\u7f16\u8457\u76844\u00a0\u90e8\u4e13\u8457\u5df2\u8fdb\u5165Springer\u9ad8\u4e0b\u8f7d\u4e66\u7c4d\u524d25%\u3002\u8be5\u7cfb\u5217\u4e1b\u4e66\u5df2\u6210\u4e3a\u751f\u7269\u71c3\u6599\u7814\u7a76\u6700\u65b0\u8fdb\u5c55\u548c\u7406\u8bba\u521b\u65b0\u7684\u77e5\u8bc6\u5e93\uff0c\u5b83\u5927\u5927\u589e\u52a0\u4e86\u4e2d\u56fd\u548c\u52a0\u62ff\u5927\u5728\u53ef\u518d\u751f\u80fd\u6e90\u9886\u57df\u7814\u7a76\u7684\u5f71\u54cd\u529b\u3002<\/p>\n<p style=\"text-align: justify;\">&#8212;&#8212;&#8212;&#8212;&#8212;&#8212;&#8212;&#8212;&#8212;&#8212;&#8211;<\/p>\n<p style=\"text-align: justify;\"><strong>\u751f\u7269\u80fd\u6e90\u7ec4\u7814\u7a76\u65b9\u5411\uff1a<\/strong><\/p>\n<p style=\"text-align: justify;\">\u8f6c\u5316\u519c\u4e1a\u548c\u751f\u7269\u8d28\u5e9f\u5f03\u7269\u4e3a\u9ad8\u9644\u52a0\u503c\u7684\u71c3\u6599\uff0c\u5316\u5b66\u54c1\u548c\u751f\u7269\u5236\u54c1\u3002\u5177\u4f53\u7814\u7a76\u5185\u5bb9\u5305\u62ec\u5982\u4e0b\uff1a<\/p>\n<p style=\"text-align: justify;\">\u00a0(i)\u3001<strong>\u7eff\u8272\u6eb6\u5242<\/strong>\uff08\u51b7\u51bb\u51b0\u6676\u3001\u6c34\u70ed\u6c34\u3001\u79bb\u5b50\u6db2\u4f53\u3001\u6709\u673a\u7535\u89e3\u6db2\u3001\u8d85\u4e34\u754c\u6d41\u4f53\u7b49\uff09\u7684\u7814\u53d1\u4e0e\u5e94\u7528\uff08\u9884\u5904\u7406\u548c\u751f\u7269\u71c3\u6599\u5408\u6210\uff09\uff0c\u53cc\u529f\u80fd\u50ac\u5316\u5242\u5408\u6210\u53ca\u7528\u4e8e\u50ac\u5316\u751f\u7269\u8d28\u751f\u4ea7\u6db2\u4f53\u71c3\u6599\u548c\u5316\u5b66\u54c1\u7b49;<\/p>\n<p style=\"text-align: justify;\">(ii)\u3001<strong>\u6c34\u70ed\u8f6c\u5316<\/strong>\uff08\u5feb\u901f\u6c34\u89e3\u7ea4\u7ef4\u7d20\u3001\u6728\u8d28\u7ea4\u7ef4\u7d20\u751f\u4ea7\u53ef\u53d1\u9175\u7cd6\u3001\u6709\u673a\u9178\u548c\u5316\u5b66\u54c1\u7b49\uff1b\u6c34\u70ed\u6c14\u5316\uff09\uff0c\u70ed\u89e3\u548c\u71c3\u70e7\u6280\u672f\u548c\u88c5\u7f6e\u7684\u5f00\u53d1\u4e0e\u5e94\u7528\uff1b<\/p>\n<p style=\"text-align: justify;\">(iii)\u3001<strong>\u5fae\u751f\u7269\u53d1\u9175<\/strong>\u6cd5\u8f6c\u5316\u6728\u8d28\u7ea4\u7ef4\u7d20\u6c34\u89e3\u4ea7\u7269\u751f\u4ea7\u6cb9\u8102\uff08\u751f\u7269\u67f4\u6cb9\uff09\u3001\u9187\u3001\u916e\u3001\u6709\u673a\u9178\u3001\u6c22\u6c14\u548c\u6cbc\u6c14\u53ca\u5176\u5b83\u6b21\u7ea7\u4ee3\u8c22\u4ea7\u7269\uff0c\u5fae\u751f\u7269\u53d1\u9175\u6cd5\u8f6c\u5316\u526f\u4ea7\u54c1\u7518\u6cb9\u751f\u4ea7\u4e73\u9178\u3001\u4e19\u4e8c\u9187\u7b49\u5316\u5b66\u54c1\uff1b<\/p>\n<p style=\"text-align: justify;\">(iv)\u3001\u7eb3\u7c73\u548c\u56fa\u4f53\u50ac\u5316\u5242\u7684\u5236\u5907\u53ca\u5e94\u7528\uff0c\u5305\u62ec\u50ac\u5316\u690d\u7269\u6cb9<strong>\u5236\u5907\u751f\u7269\u67f4\u6cb9<\/strong>\u3001\u9884\u5904\u7406\u548c\u50ac\u5316\u6728\u8d28\u7ea4\u7ef4\u7d20\u6c34\u89e3\u5e76\u751f\u4ea7\u53ef\u53d1\u9175\u7cd6\u3001\u5408\u6210\u5316\u5b66\u54c1\u548c\u751f\u7269\u71c3\u6599\u7b49\uff1b<\/p>\n<p style=\"text-align: justify;\">(v)\u3001<strong>\u80fd\u6e90\u653f\u7b56<\/strong>\u548c\u89c4\u5212\uff0c\u80fd\u6e90\u7cfb\u7edf\u4f18\u5316\u548c\u8bc4\u4ef7\u3002<\/p>\n","protected":false},"excerpt":{"rendered":"<p>1.Hydrolysis of lignocellulosic wastes Fast hydrolysis, [&hellip;]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":0,"menu_order":2,"comment_status":"open","ping_status":"closed","template":"","meta":{"footnotes":""},"_links":{"self":[{"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/pages\/94"}],"collection":[{"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/pages"}],"about":[{"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/types\/page"}],"author":[{"embeddable":true,"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/users\/1"}],"replies":[{"embeddable":true,"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/comments?post=94"}],"version-history":[{"count":21,"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/pages\/94\/revisions"}],"predecessor-version":[{"id":6126,"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/pages\/94\/revisions\/6126"}],"wp:attachment":[{"href":"https:\/\/woodrefinery.com\/zhenfang\/wp-json\/wp\/v2\/media?parent=94"}],"curies":[{"name":"wp","href":"https:\/\/api.w.org\/{rel}","templated":true}]}}