姓名:陈安伟
出生年月:1987年12月
职称:教授
电话:15243676426
E-mail: anweihuanjing@126.com
个人简介
陈安伟,博士,教授,湖南衡阳人,博士生导师。2014年博士毕业于湖南大学环境科学与工程专业,获工学博士学位,同年以“人才引进”方式入职湖南农业大学。国家注册二级建造师(市政),国务院-教育部博士生学术新人奖获得者(2012),湖南农业大学“1515”学术骨干人才(2018),RSC TOP1%高被引作者(2019),第六届国际优秀青年科学家奖获得者(2023)。先后主持国家自然科学基金2项,湖南省自然科学基金3项,长沙市自然科学基金1项,湖南省教育厅科研项目3项,湖南省生态环境厅项目、湖南农业大学引进人才基金和青年基金各1项,参与国家自然科学基金等国家级和省部级科研项目多项。以第一作者/通讯作者先后在Environmental Science & Technology,Applied Catalysis B: Environmental,Chemical Engineering Journal,Journal of Hazardous Materials等本领域权威刊物发表SCI论文60余篇,其中8篇入选ESI Hot Paper,获授权国家发明专利20余项,出版专著1部。受邀多次在国际会议上做学术报告。
研究兴趣
(1)功能微生物对重金属和有机污染水土环境的修复及其生物学响应;
(2)农林固体废物资源化高值化利用。
工作经历
2014/7-至今 先后担任湖南农业大学 讲师、副教授、硕士生导师、博士生导师、教授
2015/12‒2016/06The University of Hong Kong,School of Biological Sciences,访问学者/Research Assistant
受教育经历
2005/09‒2009/06河北理工大学 环境工程 本科/学士
2009/09‒2014/06湖南大学 环境科学与工程 博士研究生/博士(硕博连读)
教学情况
[1] 本科生课程:《专业导论》、《环境地学原理》、《环境修复理论与技术》
[2] 研究生课程:《污染生态与生态毒理》、《环境生物技术》
[3] 湖南省普通本科高校教学改革研究-重点项目,教育数字化背景下《环境修复理论与技术》课程建设改革与创新,202401000674,主持
[4] 湖南农业大学学位与研究生教育教学改革研究项目,地方农业院校研究生学术能力提升研究,2018,主持
[5] 湖南农业大学教学改革研究项目,面向环境科学专业“环境地质学”课程体系与教学改革研究,B2015164,主持
学术兼职
2019.04- 国家自然科学基金委 工程与材料科学学部地球科学部 函评专家
2022.08 《Polymers》专刊 专刊主编(Guest Editor)
2022.12 《Separations》专刊 专刊编辑(Guest Editor)
2024.04- 能源材料与器件专家委员会委员
主要科研项目
[1] 湖南省自然科学基金-面上项目,低共熔溶剂循环对秸秆水热转化为高值平台化合物的影响机制(2024JJ5205),2024/01-2026/12,主持,在研
[2] 长沙市自然科学基金项目,氯化胆碱类DES循环使用对秸秆产呋喃化合物的影响及其机理(kq2402122),2024/01-2025/12,主持,在研
[3] 湖南省生态环境厅科研项目,重金属污染秸秆衍生催化剂的制备及其对新烟碱农药降解与生物质的催化转化研究(HBKT-2022005),2022/10-2024/10,主持,在研
[4] 国家重点研发计划项目-子课题,生态和农艺因素驱动农产品镉砷累积的关键界面过程与调控(2022YFD1700102-02),2022/08-2026/12,参与,在研
[5] 湖南省教育厅优秀青年项目,非贵双金属修饰分子筛催化富重金属秸秆直接产呋喃二甲酸及其机理研究(21B0182),2021/09-2023/12,主持,已结题
[6] 国家自然科学基金-面上项目,白腐真菌强化修复新烟碱农药污染洞庭湖湿地的作用机制及微生物群落响应研究(51879105),2019/01-2022/12,主持,已结题
[7] 湖南省自然科学基金-面上项目,基于白腐真菌强化的微生物修复新烟碱农药污染湿地及其作用机制研究(2019JJ40128),2019/01-2021/12,主持,已结题
[8] 湖南省教育厅优秀青年项目,新烟碱农药污染土壤的功能微生物强化修复行为机理及微生态效应研究(18B095),2019/03-2020/12,主持,已结题
[9] 国家自然科学基金-青年基金,硫化氢在白腐真菌抗重金属胁迫中的作用及其机制(51508186),2016/01-2018/12,主持,已结题
[10] 湖南省自然科学基金-青年项目,钙对白腐真菌耐受和富集重金属的影响及其机理(2016JJ3076),2016/05-2018/12,主持,已结题
[11] 湖南省教育厅科学研究项目,白腐真菌对重金属—有机物复合污染胁迫的响应及其潜在抗胁迫能力(15C0654),2015/07-2018/06,主持,已结题
[12] 湖南农业大学青年基金,钙对白腐真菌生长、耐受和富集重金属及其功能基因表达特性的影响(15QN32),2015/09-2017/012,主持,已结题
[13] 湖南农业大学人才引进项目,废水处理中白腐真菌对抗环境毒性污染物胁迫的生理响应机制(14YJ07),2015/09-2017/07,主持,已结题
获奖荣誉
[1] 长沙市自然科学优秀学术成果二等奖(2015)
[2] 湖南省自然科学三等奖(2022)
[3] 第6届国际优秀青年科学家奖(2023)
[4] 第九届湖南省“互联网+”大学生创新创业大赛优秀创新创业导师(2023)
科研成果
1. 代表性授权发明专利
[1] 陈安伟,柴友正,白马,彭亮,尚翠,邵继海,罗斯.【专利名称】:利用秸秆制备2,5-呋喃二甲酸的方法.【专利号】:ZL20211101427.0【授权公告日】:2023年8月1日
[2] 陈安伟,尚翠,秦普丰,邵继海,雷鸣,张嘉超.【专利名称】:磁性复合吸附剂去除废水中四环素的方法.【专利号】:ZL201710385884.0【授权公告日】:2019年11月1日
[3] 陈安伟,雷鸣,尚翠,林毅青,邵继海,彭亮,曾清如.【专利名称】:磁性氢氧化镁吸附剂去除废水中四环素的方法.【专利号】:ZL201710386614.1【授权公告日】:2019年11月1日
[4] 曾光明,陈安伟,陈桂秋,范佳琦,邹正军,张文娟,王亮.【专利名称】:利用黄孢原毛平革菌同时处理废水中镉和二氯酚的方法.【专利号】:ZL201010528030.1【授权公告日】:2012年7月4日
[5] 陈安伟,曾光明,陈桂秋,胡新将,官嵩,尚翠,邹正军.【专利名称】:多功能复合吸附剂及其制备方法和应用.【专利号】:ZL201110258143.9【授权公告日】:2013年6月26日
[6] 陈安伟,曾光明,陈桂秋,晏铭,尚翠,张企华,易斌,黄健,郭志,左亚男.【专利名称】:硫化氢促进黄孢原毛平革菌降解废水中2,4-二氯酚的方法.【申请号】:ZL201310459274.2【授权公告日】:2015年04月22日
[7] 陈安伟,曾光明,陈桂秋,刘亮,尚翠,张企华,易斌,周颖.【专利名称】:重金属胁迫下黄孢原毛平革菌活细胞生物量的检测方法.【专利号】:201310305536.X【授权公告日】:2015年09月23日
2. 著作教材
[1] 陈桂秋,曾光明,陈安伟等. 废水处理中白腐真菌的化学生物学. 科学出版社,2016.11
3. 部分代表性论文
I. 功能微生物/环境污染治理与修复方向
[1] Zeng G.M.*,Chen A.W., Chen G.Q., Hu X.J., Guan S., Shang C., Lu L.H., Zou Z.J. Response ofPhanerochaete chrysosporiumto toxic pollutants: physiological flux, oxidative stress and detoxification.Environmental Science & Technology, 2012, 46(14): 7818–7825.
[2] Zhu S., Chen A.*, Chai Y., Cao R., Zeng J., Bai M., Peng L., Shao J., Wang X. Extracellular enzyme mediated biotransformation of imidacloprid by white-rot fungus Phanerochaete chrysosporium: Mechanisms, pathways, and toxicity. Chemical Engineering Journal 472 (2023) 144798.
[3] Shang C., Chen A.*, Cao R., Luo S., Shao J., Zhang J., Peng L., Huang H. Response of microbial community to the remediation of neonicotinoid insecticide imidacloprid contaminated wetland soil by Phanerochaete chrysosporium. Chemosphere 311 (2023) 136975.
[4] Li W., Chen A.*, Shang C., Zhang X., Chai Y., Luo S., Shao J., Peng L. Remediation of thiamethoxam contaminated wetland soil by Phanerochaete chrysosporium and the response of microorganisms. Journal of Environmental Chemical Engineering 10 (2022) 108333.
[5] Chen A.*, Li W., Zhang X., Shang C., Luo S., Cao R., Jin D. Biodegradation and detoxification of neonicotinoid insecticide thiamethoxam by white-rot fungus Phanerochaete chrysosporium. Journal of Hazardous Materials 417 (2021) 126017.
[6] Cao R.1, Qin P.1, Li W., Shang C., Chai Y., Jin D., Chen A*. Hydrogen sulfide and calcium effects on cadmium removal and resistance in the white-rot fungus Phanerochaete chrysosporium. Applied Microbiology and Biotechnology, 2021, 105: 6451–6462.
[7] Xie Q., Xue C., Chen A.*, Shang C., Luo S. Phanerochaete chrysosporium-driven quinone redox cycling promotes degradation of imidacloprid. International Biodeterioration & Biodegradation 151 (2020) 104965.
[8] Huang Z., He K., Song Z., Zeng G.*, Chen A.*, Yuan L., Li H., Chen G. Alleviation of heavy metal and silver nanoparticle toxicity and enhancement of their removal by hydrogen sulfide in Phanerochaete chrysosporium. Chemosphere, 2019, 224: 554–561.
[9] Zhang X., Shao J., Chen A.*, Shang C., Hu X., Luo S., Lei M., Peng L., Zeng Q. Effects of cadmium on calcium homeostasis in the white-rot fungus Phanerochaete chrysosporium. Ecotoxicology and Environmental Safety, 2018, 157: 95–101
[10] Chen A.*, Shang C., Zeng G.*, Chen G., Shao J., Zhang J., Huang H. Extracellular secretions of Phanerochaete chrysosporium on Cd toxicity. International Biodeterioration & Biodegradation, 2015, 105: 73–79.
[11] Chen A., Zeng G.*, Chen G., Zhang C., Shang C., Hu X., Lu L., Chen M., Guo Z., Zuo Y. Hydrogen sulfide alleviates 2,4-dichlorophenol toxicity and promotes its degradation in Phanerochaete chrysosporium. Chemosphere, 2014, 109: 208–212.
[12] Chen A., Zeng G.*, Chen G., Liu L., Shang C., Hu X., Lu L., Chen M., Zhou Y., Zhang Q. Plasma membrane behavior, oxidative damage, and defense mechanism in Phanerochaete chrysosporium under cadmium stress. Process Biochemistry, 2014, 49(4): 589–598.
[13] Chen A., Zeng G.*, Chen G., Fan J., Zou Z., Li H., Hu X., Long F. Simultaneous cadmium removal and 2,4-dichlorophenol degradation from aqueous solutions byPhanerochaete chrysosporium.Applied Microbiology and Biotechnology, 2011, 91(3): 811–821.
[14] Hu L., Wan J., Zeng G.*, Chen A.*, Chen G., Huang Z., He K., Cheng M., Zhou C., Xiong W., Lai C., Xu P. Comprehensive evaluation of the cytotoxicity of CdSe/ZnS quantum dots in Phanerochaete chrysosporium by cellular uptake and oxidative stress. Environ. Sci.: Nano, 2017, 4: 2018–2029. (Hot Paper)
[15] Huang Z., He K., Song Z., Zeng G.*, Chen A.*, Yuan L., Li H., Hu L., Guo Z., Chen G. Antioxidative response of Phanerochaete chrysosporium against silver nanoparticle-induced toxicity and its potential mechanism. Chemosphere, 2018, 211: 573–583.
[16] He K., Chen G., Zeng G.*, Chen A.*, Huang Z., Shi J., Huang T., Peng M., Hu L. Three-dimensional graphene supported catalysts for organic dyes degradation. Applied Catalysis B: Environmental, 2018, 228: 19–28. (Hot Paper)
[17] Bai M., Chai Y., Chen A.*, Shao J., Zhu S., Yuan J., Yang Z., Xiong J., Jin D., Zhao K., Chen Y. Co-Mn-Fe spinel-carbon composite catalysts enhanced persulfate activation for degradation of neonicotinoid insecticides: (Non) radical path identification, degradation pathway and toxicity analysis. Journal of Hazardous Materials 460 (2023) 132473.
[18] Bai M., Chai Y., Chen A.*, Yuan J., Shang C., Peng L., Peng C. Enhancing cadmium removal efficiency through spinel ferrites modified biochar derived from agricultural waste straw. Journal of Environmental Chemical Engineering 11 (2023) 109027.
[19] Shang C., Chai Y., Peng L., Shao J., Huang H., Chen A.*. Remediation of Cr(VI) contaminated soil by chitosan stabilized FeS composite and the changes in microorganism community. Chemosphere 327 (2023) 138517.
[20] Zhang H., Peng L., Chen A.*, Shang C., Lei M., He K., Luo S., Shao J., Zeng Q. Chitosan-stabilized FeS magnetic composites for chromium removal: Characterization, performance, mechanism, and stability. Carbohydrate Polymers, 2019, 214: 276–285
[21] Peng M., Chen G., Zeng G.*, Chen A.*, He K., Huang Z., Hu L., Shi J., Li H., Yuan L., Huang T. Superhydrophobic kaolinite modified graphene oxide-melamine sponge with excellent properties for oil-water separation. Applied Clay Science, 2018, 163: 63–71.
[22] He K., Zeng G.*, Chen A.*, Huang Z., Peng M., Huang T., Chen G. Graphene hybridized polydopamine-kaolin composite as effective adsorbent for methylene blue removal. Composites Part B, 2019, 161: 141–149.
[23] Wang Y., Chen A.*, Peng M., Tan D., Liu X., Shang C., Luo S., Peng L. Preparation and characterization of a fluorizated kaoline modified melamine sponge as an absorbent for efficient and rapid oil/water separation. Journal of Cleaner Production, 2019, 217: 308–316.
[24] Chen A., Shang C., Shao J.*, Lin Y., Luo S., Zhang J., Huang H., Lei M., Zeng Q. Carbon disulfide-modified magnetic ion-imprinted chitosan-Fe(III): A novel adsorbent for simultaneous removal of tetracycline and cadmium. Carbohydrate Polymers, 2017, 155: 19–27.
[25] Chen A., Shang C., Shao J.*, Zhang J., Huang H. The application of iron-based technologies in uranium remediation: A review. Science of the Total Environment 575 (2017) 1291–1306.
[26] Chen A., Zeng G.*, Chen G., Hu X., Guan S., Shang C., Lu L., Zou Z., Xie G. Novel thiourea-modified magnetic ion-imprinted chitosan-TiO2 composite for simultaneous removal of cadmium and 2,4-dichlorophenol. Chemical Engineering Journal, 2012, 191: 85–94.
II. 农林固废资源化高值化方向
[27] Chai Y., Tong Z., Al-Dhabi N. A., Zhou L., Chen A.*, Zhu S., Tang W., Ji Z., Zeng J. Upgrading lignocellulosic biomass to high-value products through the pretreatment driven by bio-based ethylene glycol solvent. Chemical Engineering Journal 496 (2024) 153797.
[28] Yang Z., Shang C.*, Bai M., Chai Y., Zhu S., Yang J., Xu Z., Chen A*. Design and synthesis of SO3H-based ionic liquids for direct catalytic conversion of straw to levulinic acid. Industrial Crops and Products, 2024, 215: 118632.
[29] Yuan J., Chen A.*, Chai Y., Bai M., Zhu S., Peng L., Zhang J. One‑pot direct conversion of raw straw to furan chemicals simultaneously in a choline chloride‑lactic acid/methyl isobutyl ketone biphasic system. Biomass Conversion and Biorefinery, 2024, https://doi.org/10.1007/s13399-024-05649-4
[30] Chai Y., Yuan J., Bai M., Chen A.*, Zhu S., Zhou L., Peng L., Shao J., Xiong J., Yang Z., Peng C., Zhou Z. Production of furan chemicals from contaminated biomass using hydrothermal-assisted activated persulfate strategy: Exploring the critical role of heavy metals on products. Chemical Engineering Journal 464 (2023) 142594.
[31] Chai Y., Bai M., Chen A.*, Xu X., Tong Z., Yuan J., Peng L., Shao J., Xiong J., Peng C. Upcycling contaminated biomass into metal-supported heterogeneous catalyst for electro-Fenton degradation of thiamethoxam: Preparation, mechanisms, and implications. Chemical Engineering Journal 453 (2023) 139814.
[32] Chai Y., Bai M., Chen A.*, Yuan J., Peng L., Shao J., Zhang J., Qin P., Peng C., Zhou Z. Introduction of acid mine drainage in the direct production of 5-hydroxy-methylfurfural from raw biomass and expanding the use of biomass conversion residue. Bioresource Technology 364 (2022) 128094.
[33] Chai Y., Chen A.*, Bai M., Peng L., Shao J., Yuan J., Shang C., Zhang J., Huang H., Peng C. Valorization of heavy metal contaminated biomass: Recycling and expanding to functional materials. Journal of Cleaner Production 366 (2022) 132771.
[34] Chai Y., Bai M., Chen A.*, Peng L., Shao J., Luo S., Deng Y., Yan B., Peng C. Valorization of waste biomass through fungal technology: Advances, challenges, and prospects. Industrial Crops & Products 188 (2022) 115608.
[35] Chai Y., Bai M., Chen A.*, Yuan J., Peng C., Zhao D., Yan B., Qin P. Cr-Mn bimetallic functionalized USY zeolite monolithic catalyst for direct production of 2, 5-Furandicarboxylic acid from raw biomass. Chemical Engineering Journal 429 (2022) 132173.
[36] Chai Y., Bai M., Chen A.*, Peng L., Shao J., Shang C., Peng C., Zhang J., Zhou Y. Thermochemical conversion of heavy metal contaminated biomass: Fate of the metals and their impact on products. Science of the Total Environment 822 (2022) 153426.
[37] Chai Y., Yang H., Bai M., Chen A.*, Peng L., Yan B., Zhao D., Qin P., Peng C., Wang X. Direct production of 2, 5-Furandicarboxylicacid from raw biomass by manganese dioxide catalysis cooperated with ultrasonic-assisted diluted acid pretreatment. Bioresource Technology 337 (2021) 125421.
人才培养
已毕业硕士、博士研究生:
2017级硕士:张 浩(获湖南省优秀硕士学位论文)
2018级硕士:张晓晓(获研究生国家奖学金),曹若愚
2019级硕士:李文洁(获研究生国家奖学金、优秀硕士学位论文),潘佳佳
2020级硕士:白 马(西北农林科技大学 攻博),金豆豆
2021级硕士:袁佳仪
2020级博士:柴友正(获研究生国家奖学金、湖南省芙蓉学子·榜样力量、清华博士后、水木学者)
已毕业优秀本科生:
2015级 谢清如(保送至 中国科学院广州地球化学研究所 直接攻博)
2016级 王宇杰(中国科学院重庆绿色智能技术研究院 攻读硕士研究生)
在读博士研究生:
2022级 朱式业(获省研究生科研重点项目资助),2023级 张佳乐,2024级 赵儒乐
在读硕士研究生:
熊嘉豪、杨正航、杨季朝、周芷睿、曹 雷、罗 雪
招生方向
学术型博士生(生态学)、学术型硕士生(生态学)、专业硕士(资源与环境)
欢迎具有微生物学、毒理学、生态学、生物学、环境科学与工程、化学、计算机等相关背景的同学报考!(更新日期2024.08)
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