姓名:

赖波

性别:

出生年月:

1981-3

学位:

博士

职称:

教授

电子邮箱:

laibo@scu.edu.cn;laibo1981@163.com

团队名称:

四川大学德渥群芳高级氧化技术创新团队

通讯地址:

成都市人民南路三段17号四川大学华西校区

邮编:

610041

 

【个人描述】

教授,博导,环境科学与工程系主任,国家级青年人才,中国环境科学学会青年科学家金奖、四川省青年科技奖、四川省环境科学学会青年科技奖获得者,入选全球前2%顶尖科学家榜单(2020-2021)和全球学者库“全球顶尖前10万科学家名单”(2021)。主要针对高难度化工废水和新兴污染物,开发高级氧化处理技术装备。带领的团队获“四川大学第五届德沃群芳育人文化建设优秀团队”称号,具有交叉学科背景,涵盖新型催化材料可控制备、高级氧化装置的设计和开发、催化氧化还原工艺和机制、降解机理、毒性产物分析和调控等方面研究工作。具体研究工作包括:起爆药、制药中间体、染料中间体、制革等生产行业高难度化工废水的处理技术及工程应用,医疗污水的同步消毒降解技术及装备,微污染物的高级氧化深度处理技术及装备。

主持国家级、省部级、科技成果转化和工程应用项目30余项。第一作者/通讯作者在Environ. Sci. Tech., Water Res., Appl. Catal. B: Environ., Chem. Eng. J.等期刊发表SCI论文130余篇,中科院一区论文70篇,ESI高被引论文18篇,热点论文3篇,获Elsevier Symposium on “Chemistry for a Sustainable Future” Best Paper Award。授权专利16项(转让许可8项),成功工程应用于高难度化工废水处理,获得四川省科技进步一等奖(第一)和中国环保产业协会环境技术进步一等奖(第一)。

担任四川省水安全与水污染控制工程技术研究中心执行主任;担任中国卓越行动期刊Chinese Chemical Letters执行主编/高级编委、EnvironmentFunctional Materials副主编,Water Reuse编辑,Journal of Hazardous Materials编委,Journal of Environmental Science青年编委、《水生态学杂志》编委、《土木与环境工程学报(中英文)》常务编委、《中国沼气》编委,共同筹建Chinese Chemical Letters环境学科专委会,并作为专委会成立大会暨2018年Chinese Chemical Letters环境学科前沿讨论会共同主席;培养学生获得国家奖学金22人次,四川大学学术之星3人次,全国优秀本科生毕业论文1人次,北大唐孝炎环境科学创新奖学金,中科院奥加诺奖学金、同济大学高廷耀奖学金、南京大学紫金全兴环境基金优秀学子奖等7人次。

 

【学习及工作经历】

1、2018.1—至今 四川大学吴玉章学院,指导老师

2、2018.1—至今 澳门永利唯一网址环境工程专业,系主任

3、2017.9—至今 澳门永利唯一网址环境工程专业,教授

4、2013.9—2017.9四川大建筑与环境学院环境工程专业,副教授

5、2011.10—2013.9四川大建筑与环境学院环境工程专业,博士后

6、2008.5—2011.7毕业于北京师范大学环境工程专业,获工学博士学位

7、2005.9—2008.4毕业于北京科技大学生物化工专业,获工学硕士学位

8、2001.9—2005.7毕业于北京科技大学环境工程专业,获工学学士学位

 

【主要研究领域】

1、基于铁基材料的高级氧化技术装备

2、活化过硫酸盐深度处理技术

3、高难度化工废水处理技术装备及应用

4、医院污水的同步消毒降解技术装备及应用

 

【承担的主要课程】

本科生课程:《泵与风机》(2012至今)、《水污染控制工程》(2015-2018)

研究生课程:《水处理中的高级氧化技术原理和工程应用》(2014至今)

 

代表性科研项目】

[1]国家级青年人才资助项目,2020.01-2023.12

[2]自然科学基金面上项目,52070133,2021.01-2024.12

[3]四川省科技厅科技成果转移转化示范项目,20ZHSF0257,2020.01-2021.12

[4]校企共建“制革废水处理技术研发联合实验室”项目,2020.12-2023.12

[5]校企共建“电化学废水处理技术联合实验室”项目,2020.6-2023.6

[6]自然科学基金面上项目,51878423,2019.01-2022.12

[7]四川省杰出青年科技人才,2019.01-2021.12

[8]四川省重点研发项目,2019YFG0314,2019.01-2020.12

[9]四川某起爆药生产废水处理技术开发及工程化应用,2017.1-2020.12

[10]环保部专项计划项目(西南地区子课题),2111101-06,2016-2019

【代表性论文】

[1]K.X. Wei, A. Armutulu, Y.X. Wang, G. Yao, R.Z. Xie*,B. Lai*,Visible-light-driven removal of atrazine by durable hollow core-shell TiO2@LaFeO3 heterojunction coupling with peroxymonosulfate via enhanced electron-transfer.Appl. Catal. B: Environ. (2022) 120889.

[2]M.F. Luo, H.Y. Zhou, P. Zhou, L.D. Lai, W. Liu, Z.M. Ao, G. Yao, H. Zhang*,B. Lai*,Metal-free Black-red Phosphorus as an Efficient Heterogeneous Reductant to Boost Fe3+/Fe2+ Cycle for Peroxymonosulfate Activation.Water Res.,188 (2021) 116529.

[3]H.Y. Zhou, J.L. Peng, J.Y. Li, J.J. You, L.D. Lai, R. Liu, Z.M. Ao, G. Yao,B. Lai*,Insights into the role of in-situ and ex-situ hydrogen peroxide for enhanced ferrate (VI) towards oxidation of organic contaminants.Water Res.,203(2021) 117548.

[4]J.L. Peng, P. Zhou, H.Y. Zhou, W. Liu, H. Zhang, C.Y. Zhou, L.D. Lai, Z.M. Ao, S.J. Su,B. Lai*,Insights into the Electron-Transfer Mechanism of Permanganate Activation by Graphite for Enhanced Oxidation of Sulfamethoxazole.Environ. Sci. Tech.,55 (2021) 9189-9198.

[5]J.Y. Li, Z.K. Xiong*, Y.H. Yu, X.H. Wang, H.Y. Zhou, B.K. Huang, Z.L. Wu, C.X. Yu, T.T. Chen, Z.C. Pan, G. Yao,B. Lai*,Efficient degradation of carbamazepine by electro-Fenton system without any extra oxidant in the presence of molybdate: The role of slow release of iron ions.Appl. Catal. B: Environ.298 (2021) 120506.

[6]L.D. Lai, P. Zhou, H.Y. Zhou, M.L. Sun, Y. Yuan, Y. Liu, G. Yao,B. Lai*,Heterogeneous Fe(III)/Fe(II) circulation in FeVO4 by coupling with dithionite towards long-lasting peroxymonosulfate activation: Pivotal role of vanadium as electron shuttles.Appl. Catal. B: Environ.297 (2021) 120470.

[7]L.D. Lai, H.D. Ji, H. Zhang, R. Liu, C.Y. Zhou, W. Liu, Z.M. Ao, N.W. Li, C. Liu*, G. Yao,B. Lai*, Activation of Peroxydisulfate by V-Fe Concentrate Ore for Enhanced Degradation of Carbamazepine: Surface ≡V(III) and ≡V(IV) as Electron Donors Promoted the Regeneration of ≡Fe(II).Appl. Catal. B: Environ.282 (2021) 119559

[8]H.Y. Zhou, H. Zhang, Y.L. He, B.K. Huang, C.Y. Zhou, G. Yao,B. Lai*, Critical Review of Reductant-enhanced Peroxide Activation Process: Trade-off between Accelerated Fe3+/Fe2+ Cycle and Quenching Reactions.Appl. Catal. B: Environ.286 (2021) 119900.

[9]Y.D. Dong, H. Zhang, G.J. Zhong*, G. Yao,B. Lai*, Cellulose/carbon Composites and their Applications in Water Treatment-a Review,Chem. Eng. J., 405 (2021) 126980.

[10]Z.K. Xiong, J.Y. Li, Y. Li, Y. Yuan, Y.N. Jiang, G. Yao,B. Lai*, Simultaneously enhanced degradation of N, N-dimethylacetamide and reduced formation of iron sludge by an efficient electrolysis catalyzed ozone process in the presence of dissolved silicate.J. Hazard. Mater.,406 (2021) 124725.

[11]Z.L. Wu, Y.P. Wang, Z.K. Xiong*, Z.M. Ao, S.Y. Pu, G. Yao,B. Lai*, Core-shell magnetic Fe3O4@Zn/Co-ZIFs to activate peroxymonosulfate for highly efficient degradation of carbamazepine.Appl. Catal. B: Environ.277 (2020) 119136.

[12]Z.Y. Shen, H.Y. Zhou, Z.C. Pan, Y. Guo, Y. Yuan*, G. Yao,B. Lai*, Degradation of atrazine by Bi2MoO6 activated peroxymonosulfate under visible light irradiation,J. Hazard. Mater.,400 (2020) 123187.

[13]M.J. Xu, H.Y. Zhou, Z.L. Wu, N.W. Li*, Z.K. Xiong, G. Yao,B. Lai*, Efficient degradation of sulfamethoxazole by NiCo2O4modified expanded graphite activated peroxymonosulfate: Characterization, mechanism and degradation intermediates,J. Hazard. Mater.,399 (2020) 123103.

[14]F. Liu, H.Y. Zhou, Z.C. Pan, Y. Liu*, G. Yao, Y. Guo,B. Lai*, Degradation of sulfamethoxazole by cobalt-nickel powder composite catalyst coupled with peroxymonosulfate: performance, degradation pathways and mechanistic consideration,J. Hazard. Mater.,400 (2020) 123322.

[15]Y.H. Zhang, L. Wang, Z.K. Xiong, W.G. Wang, D. Zheng, T. He, Y. Liu, Y. Ran, L.W. Deng*,B. Lai*, Removal of antibiotic resistance genes from post-treated swine wastewater by mFe/nCu system,Chem. Eng. J., 400 (2020) 125953.

[16]J.J. You, W.Y. Sun, S.J. Shu, Z.M. Ao, C. Liu*, G. Yao,B. Lai*, Degradation of bisphenol A by peroxymonosulfate activated with oxygen vacancy modified nano-NiO-ZnO composite oxides: A typical surface-bound radical system,Chem. Eng. J., 400 (2020) 125915.

[17]J.L. Peng, H.Y. Zhou, W. Liu, Z.M. Ao, H.D. Ji, Y. Liu*, S.J. Su, G. Yao,B. Lai*, Insights into heterogeneous catalytic activation of peroxymonosulfate by natural chalcopyrite: pH-dependent radical generation, degradation pathway and mechanism,Chem. Eng. J., 397 (2020) 125387.

[18]Y.L. He, J.L. Zhang, H.Y. Zhou, G. Yao,B. Lai*, Synergistic multiple active species for the degradation of sulfamethoxazole by peroxymonosulfate in the presence of CuO-Fe0,Chem. Eng. J., 380 (2020) 122568.

[19]Y.C. Hong, H.Y. Zhou, Z.K. Xiong*, Y. Liu, G. Yao,B. Lai*, Heterogeneous activation of peroxymonosulfate by CoMgFe-LDO for degradation of carbamazepine: Efficiency, mechanism and degradation pathways,Chem. Eng. J., (2020) 123604.

[20]Y.J. Li, J. Li, Y.T. Pan, Z.K. Xiong*, G. Yao, R.Z. Xie,B. Lai*, Peroxymonosulfate activation on FeCo2S4 modified g-C3N4(FeCo2S4-CN): Mechanism of singlet oxygen evolution for nonradical efficient degradation of sulfamethoxazole,Chem. Eng. J., 384 (2020) 123361.

[21]J.L. Zhang, Z.K. Xiong, J. Wei*, Y.H. Song, Y.Z. Ren, D.Y. Xu,B. Lai*, Catalytic ozonation of penicillin G using cerium-loaded natural zeolite (CZ): Efficacy, mechanisms, pathways and toxicity assessment,Chem. Eng. J., 383 (2020) 123144.

[22]H.Y. Zhou, L.D. Lai, Y.J. Wan, Y.L. He, G. Yao,B. Lai*, Molybdenum disulfide (MoS2): A versatile activator of both peroxymonosulfate and persulfate for the degradation of carbamazepine,Chem. Eng. J., 384 (2020) 123264.

[23]L.D. Lai, H.Y. Zhou, H. Zhang, Z.M. Ao, Z.C. Pan, Q.X. Chen, Z.K. Xiong*, G. Yao,B. Lai*, Activation of peroxydisulfate by natural titanomagnetite for atrazine removal via free radicals and high-valent iron-oxo species,Chem. Eng. J., 387 (2020) 124165.

[24]Z.K. Xiong, H. Zhang, W.C. Zhang,B. Lai*, G. Yao, Removal of nitrophenols and their derivatives by chemical redox: A review,Chem. Eng. J.,359 (2019) 13-31.

[25]J.F. Yan, J. Li, J.L. Peng, H. Zhang, Y.H. Zhang,B. Lai*, Efficient degradation of sulfamethoxazole by the CuO@Al2O3(EPC) coupled PMS system: optimization, degradation pathways and toxicity evaluation,Chem. Eng. J.,359 (2019) 1097-1110.

[26]F.Z. Ji, H. Zhang, X.X. Wei, Y.H. Zhang,B. Lai*, Efficient degradation of atrazine by Co-NZ catalyst prepared by electroless plating in the presence of peroxymonosulfate: Characterization, performance and mechanistic consideration,Chem. Eng. J.,359 (2019) 1316-1326.

[27]J. Li, J.F. Yan, G. Yao, Y.H., Zhang,B. Lai*, Improvement the degradation of atrazine in aqueous solution by CuFe2O4 as both particle electrode and catalyst for persulfate activation,Chem. Eng. J.,361 (2019) 1317-1332.

[28]M.J. Xu, J. Li, Y. Yan, X.G. Zhao, J.F. Yan, Y.H. Zhang,B. Lai*, X. Chen, L.P. Song, Catalytic degradation of sulfamethoxazole through peroxymonosulfate activated with expanded graphite loaded CoFe2O4particles,Chem. Eng. J.,369 (2019) 403-413.

[29]R.J. Zhang, Y.J. Wan, J.L. Peng, G. Yao, Y.H. Zhang,B. Lai*, Efficient degradation of atrazine by LaCoO3/Al2O3catalyzed peroxymonosulfate: Performance, degradation intermediates and mechanism,Chem. Eng. J.,372 (2019) 796-808.

[30]J.Y. Cao, L.D. Lai,B. Lai*, G. Yao, X. Chen, L.P. Song,Degradation of tetracycline by peroxymonosulfate activated with zero-valent iron: performance, intermediates, toxicity and mechanism,Chem. Eng. J.,364 (2019) 45-56.

[31]Y.C. Hong, J.L. Peng, X.G. Zhao, Y. Yan,B. Lai*, G. Yao,Efficient degradation of atrazine by CoMgAl layered double oxides catalyzed peroxymonosulfate: Optimization, degradation pathways and mechanism,Chem. Eng. J.,370 (2019)354-363

[32]Y.J. Li, X.G. Zhao, Y. Yan, J.F. Yan, Y.T. Pan, Y.H. Zhang,B. Lai*, Enhanced sulfamethoxazole degradation by peroxymonosulfate activation with sulfide-modified microscale zero-valent iron (S-mFe0): Performance, mechanisms, and the role of sulfur species,Chem. Eng. J.,376 (2019) 121302.

[33]J. Li, Y.J. Wan, Y.J. Li, G. Yao,B. Lai*, Surface Fe(III)/Fe(II) cycle promoted the degradation of atrazine by peroxymonosulfate activation in the presence of hydroxylamine,Applied Catalysis B: Environmental,256 (2019) 117782.

[34]Z.K. Xiong,B. Lai*, P. Yang, Insight into a highly efficient electrolysis-ozone process for N,N -dimethylacetamide degradation: Quantitative analysis of the role of catalytic ozonation, fenton-like and peroxone reactions,Water Res.,140 (2018)12-23.

[35]J.F. Yan, J.L. Peng, L.D. Lai, F.Z. Ji, Y.H. Zhang,B. Lai*, Q.X. Chen, G. Yao, X. Chen, L.P. Song, Activation CuFe2O4by Hydroxylamine for Oxidation of Antibiotic Sulfametheoxazole,Environ. Sci. Tech.,52 (2018)14302-14310.

[36]J. Li, M.J. Xu, G. Yao,B. Lai*, Enhancement of the degradation of atrazine through CoFe2O4activated peroxymonosulfate (PMS) process: kinetic, degradation intermediates, and toxicity evaluation,Chem. Eng. J.,348 (2018) 1012-1024.

[37]L.D. Lai, H.Y. Zhou,B. Lai*,Heterogeneous degradation of bisphenol A by peroxymonosulfate activated with vanadium-titanium magnetite: Performance, transformation pathways and mechanism.Chem. Eng. J.,349 (2018) 633-645.

[38]J. Li, Y. Ren, L.D. Lai,B. Lai*, Electrolysis assisted persulfate with annular iron sheet as anode for the enhanced degradation of 2, 4-dinitrophenol in aqueous solution.J. Hazard. Mater.,344 (2018) 778-787.

[39]L.D. Lai, J.F. Yan, J. Li,B. Lai*, Co/Al2O3-EPM asperoxymonosulfate activator forsulfamethoxazole removal: Performance, biotoxicity, degradation pathways and mechanism.Chem. Eng. J.,343 (2018) 676-688.

[40]J.Y. Cao, Z.K. Xiong,B. Lai*, Effect of initial pH on the tetracycline (TC) removal by zero-valent iron: adsorption, oxidation and reduction.Chem. Eng. J.,343 (2018) 492-499.

[41]J.L. Peng, X.H. Lu, X. Jiang, Y.H. Zhang, G. Yao,B. Lai*, Degradation of atrazine by persulfate activation with copper sulfide (CuS): Kinetics study, degradation pathways and mechanism.Chem. Eng. J.,354 (2018) 740-752.

[42]J. Li, Q. Liu, Q.Q. Ji,B. Lai*,Degradation ofp-nitrophenol (PNP) in aqueous solution by Fe0-PM-PS system through response surface methodology (RSM).Appl. Catal. B: Environ.200 (2017) 633-646.

[43]J. Li, Y. Ren, F.Z. Ji,B. Lai*, Heterogeneous catalytic oxidation for the degradation ofp-nitrophenol in aqueous solution by persulfate activated with CuFe2O4magnetic nano-particles.Chem. Eng. J.,324 (2017) 63-73.

[44]Y. Ren, J.H. Yang, J. Li,B. Lai*, Strengthening the reactivity of Fe0/(Fe/Cu) by premagnetization: implications for selectivity and rate for nitrate reduction.Chem. Eng. J.,330 (2017) 813-822.

[45]Y. Yuan,B. Lai*, Y.Y. Tang,Combined Fe0/air and Fenton process for the treatment of dinitrodiazophenol (DDNP) industry wastewater.Chem. Eng. J., 283 (2016)1514-1521.

[46]Y. Ren, Y. Yuan,B. Lai*, Y.X. Zhou, J.L. Wang,Treatment of reverse osmosis (RO) concentrate by the combined Fe/Cu/air and Fenton process (1stFe/Cu/air-Fenton-2ndFe/Cu/air).J. Hazard. Mater., 302 (2016) 36-44.

[47]Q.Q. Ji,Y. Yuan,B. Lai*, P. Yang, Y.X. Zhou,Pretreatment of ultra-high concentration wastewater from halogen-free flame retardant resin manufacturing by chemical precipitation, reduction and oxidation.J. Hazard. Mater., 308 (2016) 276-284.

[48]Z.K. Xiong, Y. Yuan,B. Lai*, P. Yang, Y.X. Zhou,Degradation ofp-nitrophenol (PNP) in aqueous solution bya novel micro-sizeFe0/O3process (mFe0/O3): Optimization, kinetic, performance and mechanism,Chem. Eng. J.302 (2016) 137-145.

[49]Z.K. Xiong,B. Lai*, P. Yang, Y.X. Zhou, J.L. Wang, S.P. Fang,Comparative study on the reactivity of Fe/Cu bimetallic particles and zero valent iron (ZVI) under different conditions of N2, air or without aeration.J. Hazard. Mater., 297 (2015) 261-268.

[50]B. Lai*, Y.H. Zhang, Z.Y. Chen, P. Yang, Y.X. Zhou, J.L. Wang,Removal ofp-nitrophenol (PNP) in aqueous solution by themicron-scale iron-copper (Fe/Cu) bimetallic particles.Appl. Catal. B: Environ.144 (2014) 816-830.

 

【专著、译著】

[1] P. Zhou, Y. Liu, Z.K. Xiong, H. Zhang,B. Lai*, Zero Valent Iron-induced Fenton-like Oxidation Towards Water Treatment. Chemistry in the Environment, Emerging Nanotechnologies for Water Treatment. (Invited Book Chapter 12).

[2]赖波(副主编),典型地区居民金属环境总暴露量及贡献比手册(铜、锌、镍、铁、铝、钒、硒、锰、银、钡),中国环境出版集团,2019.

[3]赖波(副主编),典型地区居民金属环境总暴露量及贡献比手册(汞、镉、砷、铅、铬),中国环境出版集团,2019.

[4]周岳溪,赖波,杨柳,伏小勇等,有机精细化学品工业污染综合防治最佳可行性技术,科学工业出版社,2015.

 

【学术兼职】

[1]Chinese Chemical Letters执行主编/高级编委

[2]Environment Functional Materials副主编

[3]Water Reuse编辑

[4]Journal of Hazardous Materials编委

[5]Journal of Environmental Science青年编委

[6]《水生态学杂志》编委

[7]《土木与环境工程学报(中英文)》常务编委

[8]《中国沼气》编委

[9]中国化学快报环境学科专委会成立大会暨2018年中国化学快报环境学科前沿讨论会共同主席

[10]中国环境科学学会青年科学家分会委员会委员

[11]中国医学装备协会医院建筑与装备分会第一届分会委员医院水系统专业委员会委员

[12]四川省循环经济协会第二届理事会专家咨询委员会-专家委员

[13]四川省化学化工学会环境化学专业委员会第一届委员

[14]四川省水安全与水污染控制工程技术研究中心执行主任

[15]中国城镇供水排水协会青年工作者委员会委员

[16]成都市科学技术协会第九次代表大会代表

[17]四川省环境保护产业协会水污染防治分会专家组副组长

获奖:

[1]2021年中国环境科学学会青年科学家奖(金奖)

[2]2021年入选全球学者库“全球顶尖前10万科学家名单”

[3]2020年中国环保产业协会科技进步一等奖(第一完成人)HJJS-2020-1-02-G01

[4]2020年四川省科技进步一等奖(第一)2020-J-1-11-R01

[5]2020年四川省青年科技奖

[6]2020年四川省环境科学学会青年科技奖

[7]2020年首届川渝科技学术大会优秀论文二等奖

[8]2020年入选全球前2%顶尖科学家榜单(World’s Top 2% Scientists 2020)

[9]2020年获Elsevier Symposium on “Chemistry for a Sustainable Future” Best Paper Award.

[10]2019年获四川大学第五届“德渥群芳”育人文化建设优秀团队

[11]2019年获四川大学“探究式-小班化”教学质量优秀奖

[12]2019年获“四川大学好未来优秀学者奖”

[13]2019年获首届“安捷伦杯”Chinese Chemical Letters环境化学青年科学家奖

[14]2017年获得四川大学青年科技人才奖

[15]2017获“四川大学大学生创新创业教育优秀指导教师”

[16]2014年获“四川省学术和技术带头人后备人选”

[17]2014年获“四川大学优秀青年骨干教师”

[18]2012年获“四川大学优秀博士后”

代表性专利:

[1]赖波,杨平,耦合零价铁复合垂直流人工湿地,2013.7.24,中国,ZL201210083704.0

[2]赖波,杨平,一种脱除铁炭微电解反应器中填料表层硫化亚铁钝化膜的方法,2013.8.21,中国,ZL201210138494.0

[3]赖波,杨平,一种脱除铁炭微电解反应器中填料表层磷酸铁和磷酸亚铁钝化膜的方法,2013.12.11,中国,ZL201210138774.1

[4]赖波,李慧强,杨平,一种超声波强化微米级铁铜双金属离子处理废水的方法,2014.6.4,中国,ZL201210303778.0

[5]赖波,陈钊宇,李慧强等,一种铁铜双金属粒子子处理难降解废水的方法,2014.4.16,中国,ZL201210303734.8

[6]赖波,表面具有致密、均匀离散分布铜层的铁铜材料及其制备方法,2016.2.24,中国,ZL201410169181.0

[7]赖波,高亚硝酸盐、高碳酸盐和高COD浓度的工业废水处理方法, 2016.3.30,中国,ZL201410168503.X

[8]赖波,类芬顿反应器和有毒难降解废水处理装置及处理方法, 2017.3.22,中国,ZL201510257227.9

[9]赖波.催化臭氧化-类芬顿耦合反应器及有毒难降解废水处理方法, 2018.2.2,中国,ZL201610078196.5

[10]赖波.级氧化反应器和有毒难降解废水处理装置及处理方法,2019.2.15,中国,ZL201610573560.5

[11]赖波,任逸.负载型高级氧化催化材料及其制备方法,2019.11.5,中国,ZL201710294711.8

[12]张恒,赖波.一种高级氧化反应器,2019.4.2,中国,ZL201821232371.2

[13]赖波张恒.一种高级氧化反应器,2020.3.6,中国,ZL201920330326.9

[14]赖波,熊兆锟.电解-臭氧-缓蚀剂/电解-臭氧-双氧水-缓蚀剂耦合处理有毒难降解废水的方法,2020.10.9,中国,ZL201910970649.9

[15]赖波,熊兆锟.一种电絮凝-催化臭氧/双氧水反应器,2021.1.6,中国,ZL202021013871.4

[16]赖波张恒,刘杨,熊兆锟,何传书.一体化有毒难降解废水处理装置及处理方法,2021.9.28,中国,ZL202010821497.9

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