姓名：王荣民（Rong-Min Wang）           学历：理学博士       职称：教授（二级）

专业：高分子化学与物理                研究领域：环境友好高分子与天然高分子

Email：wangrm@nwnu.edu.cn

【个人简介】

王荣民：理学博士，教授（二级），西北师范大学高分子化学与物理专业研究生（硕士、博士生）导师；甘肃省教学名师；宝钢教育基金会优秀教师奖获得者。

1988年获西北师范大学理学学士，1991年获中科院兰州化物所理学硕士学位；1998年获中科院兰州化学物理研究所博士学位；2003- 2004日本早稻田大学博士后。1991-1992西藏大学 援藏教师；2000年中科院兰州化物所羰基合成与选择氧化国家重点实验室 客座研究员；2004- 2006日本早稻田大学（Waseda University）客座教授。2011.8-10澳大利亚RMIT大学访问学习。

甘肃省青年科技奖获得者；甘肃“五四”青年奖获得者；甘肃省“333人才工程”第一、二层次人选。入选教育部“新世纪优秀人才支持计划”。中国化学会高级会员、中国化学会农业化学专业委员会委员；IUPAC青年会员；曾担任J. Mol. Cat. A: Chem. 客座编辑（Guest Editor）与Polym. Adv. Techn.客座编辑（Editor）。

【重点研究领域和兴趣】

1、环境友好高分子材料的制备与功能研究：针对环境污染问题，开发新型环境友好高分子材料： 首次提出“高分子类卟啉金属络合物”概念，制得具有催化活化分子氧功能的新型高分子类卟啉金属络合物，实现温和条件下氧气氧化烃类化合物的反应，以期从源头解决环境污染问题。针对废水中存在营养性有机物、重金属离子等问题，开发了可用于食品加工废水处理的高分子絮凝剂、高分子吸附剂。

2、天然高分子的功能化与再利用研究：以废弃蛋白质与多糖等有机高分子、黄土为无机高分子原料，从廉价高分子角度开发与利用天然高分子资源。以期实现废弃生物质材料与廉价矿物材料的高值化再利用，推动生产的可持续发展。

3、新型功能高分子材料的合成与性能研究：以开发具有实用前景的功能材料为目标，借鉴最新高分子合成技术、功能材料制备技术，进行创新设计与合成。如：功能性高分子离子液的制备与性能研究；新型呼吸涂料的制备与调节室内湿度的功能研究；新型抗菌功能高分子材料的合成与性能；聚合物Janus微球的合成与功能研究；新型多孔材料的制备及应用研究。 

【承担项目与科研成果】

主持研究6项国家自然科学基金项目和1项教育部重点项目，参加多项国家自然科学基金项目，其中1项为国家自然科学重点项目；主持过多项省自然科学基金项目、教育厅基金项目和省环保局项目；教育部创新团队主要成员。在“J Am Chem Soc”、“Angew Chem”、“J Contr Rel”等国际国内重要学术刊物上发表论文300余篇；申请国家发明专利80余件；鉴定成果4项。获省级科技进步三等奖3项。转让应用成果8项并取得很高的经济效益。 

【主讲课程与教学成果】

主讲本科生、硕士生及博士生的《科技信息检索与论文写作》、《有机化学》、《有机化学实验》、《精细化学品化学》、《高分子化学》、《功能高分子》、《智能高分子》、《高分子合成技术》、《高分子表征技术》、《高分子前沿》等课程。其中，在“有机化学”教学过程中获得甘肃省教学成果二等奖；在“化学信息检索”“信息检索与科技论文写作”教学过程中获得甘肃省省级精品课程、省级精品资源共享课，及甘肃省教学成果二等奖等诸多奖励。作为课程负责人完成的《科技信息检索与论文写作》在线课程（智慧树平台）已有100多所学校使用。 

【专著与教材】

出版著作和教材9部（版）。主编《科技信息检索与论文写作》（科学出版社，2020.8）；主编《化学化工信息及网络资源的检索与利用》（第5版）（化学工业出版社，2021.9）；主编《高分子材料合成实验》（化学工业出版社，2019.5）；参编《精细有机品化学》（石油大学出版社，1996年）；参编《酶化学》（化学工业出版社）2007。其中，主编的《化学化工信息及网络资源的检索与利用》获全国优秀畅销书（科技类）、中国石油和化学工业优秀图书奖二等奖、中国石油和化学工业优秀出版物奖（科技类）一等奖和甘肃省教学成果奖，并于2014年入选 “国家十二五规划教材”。 

【代表性论文】

1) Zejun Wang, Bozhen Li, Jiarui Ren, Rongmin Wang*, Pengfei Song and Yufeng He*， Construction of coral rod-like MoS₂@HA nanowires hybrids for highly effective green antisepsis, Journal of Inorganic Biochemistry, 2022, 111724. （IF：4.155） 

2) Di Gao, Yaping Zhang, Haiyan Yan, Bozheng Li, Yufeng He*, Pengfei Song, Rongmin Wang*，Construction of UiO-66@MoS₂ flower-like hybrids through electrostatically induced self-assembly with enhanced photodegradation activity towards lomefloxacin, Separation and Purification Technology, 2021, 265: 118486. （IF：7.312）

3) Bin Wang, Tian Li, Wenling Guo, Rongmin Wang*, Yue Li, Xinhua Zhu, Pengfei Song, Yufeng He*，Synthesis of Ag@chitosan/copolymer with dual-active centers for high antibacterial activity, International Journal of Biological Macromolecules, 2021, 174: 198-206. ( IF：6.953 )

4) Xuemei Li, Jianxin Gan, Peng Cao, Wenling Guo, Rongmin Wang*, Pengfei Song, Yufeng He*， Preparation of blackberry-shape cationic copolymer particles for highly effective antibacterial coatings, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021, 614, 126202.

5) Bin Wang, Wenling Guo, Tian Li, Rongmin Wang*, Pengfei Song, Yufeng He*, Xiaoqi Cheng，Synthesis of Antibacterial Janus Sheets Containing Dual-active Centers by Quaternization Fracture, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021, 628, 127276. ( IF：4.539 )

6) Wenling Guo, Yulong He, Fawei Wang, Yonggang Li, Bin Wang, Rongmin Wang*, Pengfei Song*， Fabrication of AgNPs@bowl-shaped structure with excellent antibacterial activity, Colloid and Interface Science Communications, 2021, 44, 100473. ( IF：4.914 )

7) Bozhen Li, Yiming Li, Jiarui Ren, Fengli Dai, Yaping Zhang, Yufeng He*, Pengfei Song and Rongmin Wang*. Construction of CoMOF@HAnW Moniliform-like Heterojunction for Effective Catalytic Degradation of Organics, ACS Applied Nano Materials, 2021, 4, 9370-9381. ( IF：5.097 )

8) HaiyanYan, Xinhua Zhu, Fengli Dai, Yufeng He*, Xingyue Jing, Pengfei Song, Rongmin Wang*， Porous Geopolymer Based Ecofriendly Multifunctional Slow-Release Fertilizers for Promoting Plant Growth, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021, 631. 167646. ( IF：4.539 )

9) Yaping Zhang, Peiyu Cao, Xinhua Zhu, Bozhen Li, Yufeng He*, Pengfei Song, Rongmin Wang*, Facile Construction of BiOBr Ultra-thin Nano-roundels for Dramatically Enhancing Photocatalytic Activity, Journal of Environmental Management, 2021,299,113636. (IF：6.789 )

10) Fawei Wang, Bin Wang, Xuemei Li, Zhanmin Wu, Yufeng He*, Pengfei Song, Rongmin Wang*. Antimicrobial Cationic Acrylate-based Hybrid Coatings against Microorganism Contamination, Progress in Organic Coatings, 2020, 142: 105576. (IF：5.161 )

11) Bin Wang, Wenling Guo, Xiaoqing Liu, Yufeng He*, Pengfei Song, Rongmin Wang*. Fabrication of Silver-Decorated Popcorn-like Polymeric Nanoparticles for Enhanced Antibacterial Activity, Applied Surface Science, 2020, 522, 146318. (IF：6.707 )

12) Xuemei Li, Bin Wang, Tingyu Liang, Rongmin Wang*, Pengfei Song, Yufeng He*. Synthesis of cationic acrylate copolyvidone-iodine nanoparticles with double active centers and their antibacterial application. Nanoscale, 2020, 12: 21940-21950. ( IF: 7.790 )

13) Di Gao, Jing Chen, Wenzhen Qian, Yufeng He*, Pengfei Song, Rongmin Wang*. Improving wettability of feather fiber by surface modification, Waste and Biomass Valorization, 2020, 11, 6993-7003.

14) Pengfei Song, Rong Guo, Wei Ma, Liyan Wang, Fangfang Ma and Rongmin Wang. Synthesis of CO₂-based polycarbonate-g-polystyrene copolymers via NMRP, Chem. Commun., 2020, 56: 9493-9496. ( IF: 6.222 )

15) Bin Wang, Xuemei Li Yufeng He*, Pengfei Song, Rong-Min Wang*. One-pot Synthesis of Mushroom-shaped Polymeric Janus Particles by Soap-free Emulsion Copolymerization, European Polymer Journal, 2019, 113: 260-266.

16) Bin Wang, Lingyun Jia, Fawei Wang, Yufeng He*, Pengfei Song, Rong-Min Wang*. Anisotropic Nano-/Microparticles from Diversified Copolymers by Solvent-Mediated Self-Assembly, Langmuir, 2019, 35(39): 12792-12798.

17) Pengfei Song, Hao Wang, Li Kang, Baocheng Ran, Honghong Song and Rongmin Wang. Electrochemical nitrogen reduction to ammonia at ambient conditions on nitrogen and phosphorus co-doped porous carbon, Chem. Commun., 2019, 55(5): 687-690.

18) Pengfei Song, Li Kang, Hao Wang, Rong Guo, and Rongmin Wang. Nitrogen (N), Phosphorus (P)-Codoped Porous Carbon as a Metal-Free Electrocatalyst for N₂ Reduction under Ambient Conditions, ACS Appl. Mater. Interfaces, 2019, 11(13): 12408-12414.

19) Bin Wang, Zhanmin Wu, Dawei Zhang, Rong-Min Wang*, Pengfei Song, Yubing Xiong, Yufeng He*, Antibacterial silicylacrylate copolymer emulsion for antifouling coatings, Prog. Org Coating, 2018, 118: 122-128.

20) Bin Wang, Fawei Wang, Yandi Kong, Zhanmin Wu, Rong-Min Wang*, Pengfei Song, Yufeng He*, Polyurea-crosslinked Cationic Acrylate Copolymer for Antibacterial Coating, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2018, 549: 122-129.

21) Peng Cao, Yuxia Fan, Junrui Yu, Rongmin Wang, Pengfei Song, Yubing Xiong, Polypyrrole nanocomposites doped with functional ionic liquids for high performance supercapacitors, New J. Chem., 2018, 42(5): 3909-3916. 

22) Jianfeng Wang, Wenzhen Qian, Yufeng He*, Yubing Xiong, Pengfei Song, Rong-Min Wang*, Reutilization of Discarded Biomass for Preparing Functional Polymer Materials, Waste Management, 2017, 65: 11-21.

23) Tao Li, Xiao-Chun Yin, Wen-Zhong Zhai, Yu-Feng He, Rong-Min Wang*, Enzymatic Digestion of Keratin for Preparing a pH-Sensitive Biopolymer Hydrogel, Aust. J. Chem., 2016, 69(2): 191-197.

24) Wenzhong Zhai, Bin Wang, Yusheng Wang, Yu-Feng He, Pengfei Song, Rong-Min Wang*, An Efficient Strategy for Preparation of Polymeric Janus Particles with Controllable Morphologies and Emulsifiabilities, Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2016, 503: 94-100.

25) Yong Zuo, Junrui Yu, Xiaojun Liu, Peng Cao, Pengfei Song, Rongmin Wang* and Yubing Xiong*, Poly(ionic liquid)-based nanogels and their reversible photo-mediated association and dissociation, Polym. Chem., 2017, 8, 1146-1154.

26) Qizhao Wang*, Qiong Ma, Juhong Lian, Junbo Zhong, Fangping Wang, Jianzhang Li, Yu-Feng He and Rongmin Wang*, Paper Bovine serum albumin modified ZnO to degrade organic dyes under ultraviolet light irradiation, New J. Chem., 2016, 40, 5604-5610.

27) Wenzhong Zhai, Zhan-Min Wu, Xiaowen Wang, Pengfei Song, Yufeng He, Rong-Min Wang*，Preparation of Epoxy-acrylate Copolymer@Nano-TiO2 Pickering Emulsion and Its Antibacterial Activity, Progress in Organic Coatings, 2015, 87: 122-128.

28) Jie Liu, Siyao Lv, Yu-Feng He*, Fei Pei, Rong-Min Wang*, Preparation and controlla ble release behavior of edible zein hybrid nanoparticles, Journal of Controlled Release, 2015, 213, e94-e95.

29) Zhan-Min Wu, Wen-Zhong Zhai, Yu-Feng He, Peng-Fei Song, Rong-Min Wang*, Silicylacrylate Copolymer Core-Shell Emulsion for Humidity Coatings, Progress in Organic Coatings, 2014, 77(11): 1841-1847.

30) Cheng Li, Zhanmin Wu, Yu-Feng He, Peng-Fei Song, Wenzhong Zhai, Rong-Min Wang*, A facile fabrication of amphiphilic Janus and hollow latex particles by controlling multistage emulsion polymerization, Journal of Colloid and Interface Science, 2014, 426: 39-43.

31) Xuling Wei, Hui-Ru Li, Li Wang, Yu-Feng He, Rong-Min Wang *, Soybean Hulls Residue Adsorbent for Rapid Removal of Lead Ions, Pure Appl. Chem., 2014, 86(5): 711-720.

32) LI Gang, ZHANG Hui-Fang, WANG Rong-Min*, HE Yu-Feng, XIONG Yu-Bing, Preparation and Antioxidant Activity of Albumin Binding Salen Schiff-base Metal Complexes, Chinese Science Bulletin, 2013, 58(24): 2956-2963.

33) Xiao-Xiao Li, Rong-Min Wang, Yu-Feng He, Fei Pei, Ting-Ting Zhao, Feather keratin binding transition metal ions for mimicking antioxidant enzyme, Journal of Controlled Release, 2013, 172: e136-e137.

34) XC Yin, FY Li, YF He, Y Wang, RM Wang, Study on Effective Extraction of Chicken Feather Keratins and Their Films for Controlling Drug Release,  Biomaterials Science, 2013, 1, 528-536

35) SF Zhang, RM Wang, YF He, PF Song, ZM Wu, Waterborne Polyurethane-Acrylic Copolymers Crosslinked Core-Shell Nanoparticles for Humidity-Sensitive Coatings, Progress in Organic Coatings, 2013, 76, 729-735.

36) Y Xiong, J Liu, Y Wang, H Wang, RM Wang，One-Step Synthesis of Thermosensitive Nanogels Based on Highly Cross-Linked Poly(ionic liquid)s，Angew. Chem. Int. Ed. 2012, 51, 9114-9118. （IF=13.455 ）

37) YF He, L Zhang, RM Wang, HR Li, Y Wang，Loess clay based copolymer for removing Pb(II) ions, Journal of Hazardous Materials, 2012, 227/228: 334-340.

38) YF He, L Zhang, DZ Yan, SL Liu, H Wang, HR Li, RM Wang，Poly (acrylic acid) modifying bentonite with in-situ polymerization for removing lead ions, Water Science and Technology, 2012, 62: 1383-1391.

39) NP He, RM Wang, YF He, XM Dang，Fabrication, structure and surface charges of albumin-chitosan hybrids, Science China Chemistry, 2012, 55(9): 1788-1795.

40) XC Yin, XX Li, RM Wang, G Li, YF He，Bifunctional antioxidant enzyme mimics of albumin-binding salphen Schiff-base metal complexes, Pure Appl. Chem., 2012, 84(12), 2641-2651.

41) RM Wang, JF Wang, XW Wang, YF He, YF Zhu and ML Jiang, Preparation of acrylate-based copolymer emulsion and its humidity controlling mechanism in interior wall coatings, Progress in Organic Coatings, 2011, 71: 369-375.

42) CW Mao, RM Wang*, HF Zhang, YF He, JD Tao, XC Ying， A novel dual stimuli-responsive drug carrier biomaterial based on BSA/PVP polymers, Journal of Controlled Release, 2011, 152, e69-70.

43) FY Li, RM Wang, YF He, XX Li, PF Song, XC Ying, CW Mao，Keratin films from chicken feathers for controlled drug release, Journal of Controlled Release, 2011, 152, e92-93.

44) N P He, RM Wang, YF He, Y Zhou, XJ Wang, F Pei，pH-induced self-assembly of albumin and chitosan, Journal of Controlled Release, 2011, 152, e208-210.

45) T. Komatsu, R M Wang, P. A. Zunszain, S. Curry, E. Tsuchida. Photosensitized Reduction of Water to Hydrogen Using Human Serum Albumin Complexed with Zinc-Protoporphyrin IX,  J. Am. Chem. Soc., 2006, 128(50), 16297-16301 （IF：15.419）.

46) Y. Xiong*, H Wang, RM Wang*, Y Yan, B Zheng and Y Wang, A facile one-step approach to core cross-linked nanoparticles as highly efficient catalyst for cycloaddition of CO₂ to epoxides,  Chem. Commun., 2010, 46: 3399-3401.

47) RM Wang, ZF Duan, YF He, ZQ Lei. Heterogeneous catalytic aerobic oxidation behavior of Co-Na heterodinuclear polymeric complex of Salen-crown ether. J. Mol. Catal. A:Chem., 2006, 260, 280-287.

48) RM Wang, T. Komatsu, A. Nakagawa, E. Tsuchida. Human Serum Albumin Bearing Covalently Attached Iron(II) Porphyrins as O2-Coordination Sites. Bioconjugate Chem., 2005, 16(1), 23-26.

49) YB Huang, T. Komatsu, RM Wang, A. Nakagawa, E. Tsuchida. Poly(ethylene glycol) Conjugated Human Serum Albumin Including Iron Porphyrins: Surface Modification Improves the O2-Transporting Ability. Bioconjugate Chem., 2006, 17(2), 393-398.

50) RM Wang, HX Feng, YF He, CG Xia, JS Suo, YP Wang. Preparation and Catalysis of NaY-Encapsulated Mn(III) Schiff-Base Complex in Presence of Molecular Oxygen. J. Mol. Catal. A:Chem., 2000, 151/1-2, 253-259.

51) RM Wang, CJ Hao, YP Wang, SB Li. Amino Acid Schiff Base Complex Catalyst for Effective Oxidation of Olefins with Molecular Oxygen. J. Mol. Catal. A: Chem. 1999, 147(1-2) , 173-178.

52) 殷晓春，李刚，王荣民，何玉凤，熊玉兵, 金属卟啉白蛋白结合体模拟SOD酶性能研究，中国科学，2013, 41(1): 171-177. 

【近期代表性成果】 

1. 新型抗菌功能材料的合成

包括细菌、病毒在内的有害微生物防治，尤其是预防新冠病毒的传播，引起各国科学家们的高度关注。开发新型的抗菌材料是有效解决问题的重要途径之一。其中，具有抗菌功能的聚合物可用于多种用途的基材表面，如防腐、杀菌剂、水净化和食品储存等。本课题组开展了如下研究：

首先，开展了特殊形貌阳离子聚合物Janus微球的合成及其在高效抗菌涂料的应用。以常见的丙烯酸酯类单体、苯乙烯单体及阳离子单体，水为溶剂，采用一锅无皂乳液聚合法，精确控制合成工艺与条件，成功合成了具有广谱抗菌活性的黑莓形阳离子共聚物颗粒（BsCCP），并将BsCCP乳液加入到内墙涂层中，得到了BsCCP基涂料（BsCCP-C）（Scheme 1）。评价了其对大肠杆菌和金黄色葡萄球菌的抗菌活性，讨论了其抗菌机制。发现BsCCP具有高效的抗菌活性，有望成为一种能够快速有效抵抗细菌繁殖的抗菌涂层材料。该成果以论文“Preparation of blackberry-shape cationic copolymer particles for highly effective antibacterial coatings”发表在Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021, 614, 126202.（化学2区，IF：4.53）；另一篇论文“Synthesis of cationic acrylate copolyvidone-iodine nanoparticles with double active centers and their antibacterial application”发表在Nanoscale, 2020, 12, 21940-21950（工程I区，IF：7.79）。第一作者为李雪梅（硕士研究生）。

Scheme 1

其次，进行了蠕虫状共聚物Janus微球的合成及高效抗菌活性复合材料的制备。采用悬浮聚合和界面聚合相结合的方式，亲水性和疏水性单体，甲苯为软模板剂，成功合成了具有高效抗菌活性的蠕虫状共聚物Janus微球（PMS-WJMs）。然后将PMS-WJMs与银负载壳聚糖（Ag@CS）结合，制备了无机纳米微粒负载天然高分子/合成高分子（Ag@CS /PMS-WJMs）复合材料（Scheme 2）。发现合成的PMS-WJMs和Ag@CS/PMS-WJMs对典型的大肠杆菌和金黄色葡萄球菌显示出良好的抗菌活性。制备的PMS-WJMs和Ag@CS/PMS-WJMs能被用作抑制细菌感染和繁殖的新型抗菌材料，抗菌蠕虫状聚合物颗粒在新型界面材料的制中具有重要的意义。该成果以论文“Synthesis of Ag@chitosan/copolymer with dual-active centers for high antibacterial activity”发表在International Journal of Biological Macromolecules, 2021, 174: 198-206（高分子科学1区，IF：6.95），第一作者为王斌（博士研究生）。另一篇论文“Antimicrobial Cationic Acrylate-based Hybrid Coatings against Microorganism Contamination”发表在Progress in Organic Coatings, 2020, 142: 105576（材料科学I区，IF：5.16）。王发伟（硕士研究生）和王斌（博士研究生）为共同第一作者。

Scheme 2

2. 催化降解水中有机污染物材料的合成

首先，充分利用MOFs材料中UiO-66具有高比表面积、大孔隙率、高热稳定性、化学稳定性、优异的水中结构稳定性和显着的强酸性、中等碱度的耐受性等特点，通过简单的水热反应构筑了一种高光催化活性的花状杂合体异质结材料，为医疗废水的光催化处理提供了一种新思路。通过将UiO-66分散到MoS₂的前驱体溶液中，在水热反应过程中经过静电诱导自组装构建花状杂合体材料（Scheme 3）。将其应用于医疗废水抗生素的降解，探讨了花状UiO-66@MoS₂杂合体的光降解机理。发现所制备的光催化材料不但具有高的催化活性，而且可循环使用。

其次，利用高分子效应，在油包水乳液中包覆BiOBr前驱体溶液，再通过水热反应构建超薄纳米圆片（Scheme 4）。并将其应用于有机物的降解，在提升降解率的同时，还提高了传统BiOBr的循环稳定性。最后通过M-K电负性定义理论方程计算了超薄纳米圆片的带隙能和导带能，并结合自由基捕获实验探讨了BiOBr超薄纳米圆片的降解机理。利用高分子效应调控BiOBr的尺寸，构筑了比表面积更大且具有光降解活性的超薄纳米圆片，为设计和制备高效、可回收、高光响应的光催化材料净化废水提供了一些新思路。成果以论文“Construction of UiO-66@Flower-like MoS₂ hybrids through electrostatically induced self-assembly with enhanced photodegradation activity towards Lomefloxacin Chemosphere”发表在Separation and Purification Technology, 2021, 265: 118486（工程I区，IF：7.312）。高娣（硕士研究生）和张亚苹（博士研究生）为共同第一作者。另一篇论文“Facile Construction of BiOBr Ultra-thin Nano-roundels for Dramatically Enhancing Photocatalytic Activity”发表在Journal of Environmental Management, 2021, 299, 113636（环境科学与生态学2区，IF：6.79）。第一作者张亚苹（博士研究生）。

Scheme 3

Scheme 4

3. 新型农用材料的合成

以廉价的黄土微粒（Lo）为原料，采用碱激发法制备多孔黄土基地质聚合物（Lo-GP），进一步以Lo-GP作为农业肥料载体，以天然高分子、生物相容性高分子为凝胶包膜材料，将尿素进行包封，通过硼酸作为交联剂形成凝胶体，合成了一种廉价环保且能缓释肥料的多孔地质聚合物复合凝胶材料。发现其具有吸水、保水性能、土壤酸碱性调节性能；对氮肥具有较好的缓释效果，而且对植物具有促进生长作用。因此可以推广应用于农业肥料缓释中。成果论文“Porous Geopolymer Based Ecofriendly Multifunctional Slow-Release Fertilizers for Promoting Plant Growth”发表在Colloids and Surfaces A: Physicochemical and Engineering Aspects, 2021, 631. 167646（化学2区，IF：4.53）。闫海彦、朱新华为共同第一作者（硕士研究生）。

Scheme 5