国家重点研发项目首席，国家林草科技创新团队负责人，国家自然科学基金重点项目、联合重点项目负责人，吉林省B类人才、省“杰青”、省创新拔尖人才和省青年科技奖获得者；国家基金委地学函评和会评专家。兼任国家湿地研究中心秘书长（国家林业和草原局与中国科学院共建）、中国生态学会湿地生态专业委员会副主任、中国生态学会团体标准专业委员会副主任等。《湿地科学》执行主编，《应用生态学报》副主编，Wetlands（Associate Editor）、Earth Critical Zone、《湖泊科学》、《环境生态学》编委。

2025/11-至今，中国科学院沈阳应用生态研究所，党委书记，研究员

2024/01-2025/12，中国科学院长春分院，副院长，研究员

2009/07-2025/12，中国科学院东北地理与农业生态研究所，历任助理研究员、副研究员、研究员，兴凯湖站副站长，科研计划处副处长、处长，副所长

2003/09-2009/07, 中国科学院东北地理与农业生态研究所，硕士研究生，博士研究生，导师：吕宪国研究员

期间：

2012/03-2013/03, 美国佐治亚大学,访问学者

2013/12-2015/03, 澳大利亚西澳大学,访问学者

2023年10月，俄罗斯远东地区考察交流

2024年09月，俄罗斯贝加尔湖区域考察交流

2025年10月，法国巴黎和里昂科技创新与科研管理培训

湿地生态学，生物地理学，土壤生态学；湿地生态韧性构建与功能优化，泥炭地碳库稳定性响应气候变化的生物驱动，湿地生境水文连通与生物连通耦合，土壤动物对土壤碳氮循环的调控

[1] 国家自然科学基金重点项目：中高纬泥炭地土壤碳库稳定性对气候变化响应的生物驱动机制（42430511），2025.01-2029.12, 直接经费 225万。

[2] 国家重点研发计划（典型脆弱生态系统保护与修复）：东北沼泽湿地生境功能提升技术与应用（2022YFF1300900），2022.09-2026.08，1500万。

[3] 国家自然科学基金联合基金重点支持项目（区域创新发展联合基金）：长白山地土壤动物垂直格局变化对土壤碳氮循环的影响及机制（U20A2083），2021.01-2024.12，267万。

[4] 国家重点研发计划（典型脆弱生态修复与保护研究）：北方典型河口湿地生态修复与产业化技术课题（2017YFC0505900）课题：多重胁迫下河口湿地响应机理(2017YFC0505901)。2017.7-2020.12。200万

[5] 中国工程院院地合作项目：松嫩平原西部农田-草原-湿地生态连通工程战略咨询研究（JL2022-12），2022.06-2023.05, 40万。

[6] 吉林省科技发展计划项目杰出青年基金项目：松嫩平原沼泽湿地生境功能恢复与稳定性提升机制（20230101348JC）。2023.01-2025.12，60万。

[7] 国家重点研发计划（东北退化湿地恢复与重建技术及示范）子课题：退化淡水沼泽湿地恢复与重建技术及示范(2016YFC0500408-2)。2016.07-2020.12，175万。

[8] 国家自然科学基金面上项目：洪泛沼泽破碎化下水生无脊椎动物格局与食物网功能响应（41871099），2019.01-2022.12，直接经费60万。

[9] 国家自然科学基金面上项目：增温下退化沼泽土壤动物格局与其碳循环调控功能响应及机制（41671260），2017.01-2020.12，直接经费66万。

[10] 内蒙古自治区林业和草原局委托项目:内蒙古全民所有湿地资源资产委托代理机制试点项目，2022.9-2023.12，359万。

[11] GEF东亚-澳大利西亚迁飞路线中国候鸟保护网络建设委托项目：编写《候鸟迁飞通道关键栖息地生态修复技术指南》，2024.09-2026.06，20万。

[12] 大兴安岭双河源、漠河国家湿地公园湿地生态资源本底调查，2023.09-2025.06，256万。

[1] Peng Qi, Jiaxu Mu*, Haitao Wu*, Qiang Liu, Liwen Chen, Yuxiang Yuan,  Guangxin Zhang. Impacts of Different Flood Pulses' Intensities on Lateral Hydrological Connectivity and Habitats in Riparian Wetlands. Ecohydrology, 2026; 19:e70173 .https://doi.org/10.1002/eco.70173.

[2] Haitao Wu* Kangle Lu, Yuanxiang Fu, Shuqing An, Xinxin Hu, Darold P Batzer. Progresses and Challenges in Global Wetlands Conservation and Restoration: Insights from Ramsar COP15. The Innovation, 2026, 7(2): 101141.

[3] Zhenshan Xue, Shaoxia Xia, Siqi Dong, Yeqiao Wang, Lin Li, Darold P Batzer, Ming Jiang, Xianguo Lyu, Haitao Wu*. Wetland protection gaps in China: Insights from small and/or isolated wetlands (SIWs). The Innovation Geoscience, 2026, 4(1): 100179.

[4] Dandan Liu, Yiling Lin, Haitao Wu*. Investigating soil trophic links in a peatland, northeast China: Dual stable isotope analysis (δ¹³C and δ¹⁵N) of microarthropods and their food sources. European Journal of Soil Biology, 2025,126:103761.

[5] Mingzhu Lu, Wenzhi Liu, Lei Fan, Haitao Wu*. Earthworms regulate the response of greenhouse gas emissions in wetland soils to simulated warming and flooding. Applied Soil Ecology. 2025，210:106074.

[6] Zhiyu Zhang, Jie Gao, En Guan, Xiaochen Yao, Wenfeng Wang*, Zhongsheng Zhang, Haitao Wu*. Effects of polyethylene microplastics on soil microbial assembly and ecosystem multifunctionality in the remote mountain: Altitude matters. Journal of Hazardous Materials, 2025,493:138327. 

[7] Yujuan Kang, Qiang Guan, Haitao Wu*. Responses and microbial mechanisms of greenhouse gas emissions and multifunctionality of soils at different elevations in Changbai Mountain under warming conditions. Applied Soil Ecology, 2025,208:105972.

[8] Qiang Guan, Haitao Wu*, Yujuan Kang, Wenjing Tian, Dongmei Zheng, Fengzhi He. Hydrogeomorphic conditions drive aquatic macroinvertebrate diversity between depression and slope wetlands in a mountainous region. Journal of Environmental Management, 2024, 372: 123371.

[9] Zhiyu Zhang, Jiaxing Shi, Xiaochen Yao, Wenfeng Wang*, Zhongsheng Zhang, Haitao Wu*. Comparative evaluation of the impacts of different microplastics on greenhouse gas emissions, microbial community structure, and ecosystem multifunctionality in paddy soil. Journal of Hazardous Materials, 2024, 480:135958.

[10] Xue Liu, Qiong Wu, Haitao Wu*, Xiaxing Shi, Zhongsheng Zhang. Earthworm invasion and interaction with litter increased CO₂ and N₂O emissions in Changbai Mountain: A microcosm study. Applied Soil Ecology. 2024,202:105533.

[11] Kangle Lu, Zhanyan Chen, Xinhua He, Haitao Wu*, Fengzhi He. Slow recovery in trophic structure of restored wetlands in Northeast China. Science of the Total Environment, 2024.952,175803.

[12] Qiang Guan, Fengzhi He, Zhengfei Li, Yongjiu Cai, Yujuan Kang, Zhongsheng Zhang, Haitao Wu*. Contrasting diversity patterns and drivers of aquatic macroinvertebrates in floodplain and non-floodplain wetlands. Science of The Total Environment,2024, 945: 174045.

[13] Yujuan Kang,Haitao Wu*, Qiang Guan, zhongsheng Zhang, Wenfeng Wang. Earthworms and warming alter methane uptake and methane-cycling microbial community in meadow soil. Soil Ecology Letters. 2024. 6:240255.

[14] Dandan Liu, Haitao Wu*. The joint effects of local, climatic, and spatial variables determine soil oribatid mite community assembly along a temperate forest elevational gradient. Ecology and Evolution,2024,14:e11590.

[15] Wenfeng Wang, Qiang Guan, Kangle Lu, Yuxiang Yuan, Zhongsheng Zhang Haitao Wu*. The impacts of microplastics on the cycling of carbon and nitrogen in terrestrial soil ecosystems: Progress and prospects. Science of the Total Environment, 2024,913:169977.

[16] Kangle Lu, Haitao Wu*, Sonja C. Jähnig, Fengzhi He. The impacts of reduced connectivity on multiple facets of aquatic insect diversity in floodplain wetlands, Northeast China. Science of the Total Environment, 2024,912:169207.

[17] Yujuan Kang, Haitao Wu*, Qiang Guan, Zhongsheng Zhang. Responses of soil greenhouse gas emissions to soil mesofauna invasions and its driving mechanisms in the alpine tundra: A microcosm study. Science of the Total Environment, 2024,908:168255.

[18] Zhiyu Zhang, Wenfeng Wang*, Jiping Liu, Haitao Wu*. Discrepant responses of bacterial community and enzyme activities to conventional and biodegradable microplastics in paddy soil. Science of the Total Environment, 2024,909:168513.

[19] Haitao Wu, Dandan Liu, Bai Junhong, Cai Yongjiu, Li Feng. Preface: Freshwater wetlands, biodiversity, functioning, restoration and utilization. Hydrobiologia, 2023,850(18):3837-3838.

[20] Zhang Zhiyu, Kang Yujuan, Wang Wenfeng*, Xu Lei, Liu Jiping, Zhang Zhongsheng, Wu Haitao*. Low-density polyethylene microplastics and biochar interactively affect greenhouse gas emissions and microbial community structure and function in paddy soil. Chemosphere, 2023, 340:139860.

[21] Lu Kangle, Jähnig Sonja C, Wu Haitao*, Xie Zhijing, Chen, Xing, He Fengzhi. Trait-based approach of aquatic insects to track recovery of wetland ecosystems in Northeast China. Ecological Indicators, 2023,155:111012.

[22] Qiang Guan, Haitao Wu*, Lei Xu, Yujuan Kang, Kangle Lu, Dandan Liu, Dandan Han, Zhenshan Xue, Yuxiang Yuan, Wenfeng Wang, Zhongsheng Zhang. Hydrological connectivity shapes multiple diversity facets of snail (Mollusca: Gastropoda) assemblages in freshwater floodplain wetlands. Ecological Indicators, 2023,153:110467.

[23] Qiang Guan, Haitao Wu*, Xiaofeng Xu, Zhongsheng Zhang, Zhenshan Xue. Geographical and climate-­dependent patterns in spatial distributions of snail (Mollusca: Gastropoda) assemblages in freshwater wetlands across Northeast China. Freshwater Biology. 2023,68(6):1066–1078.

[24] Yujuan Kang, Haitao Wu*, Yifan Zhang, Qiong Wu, Qiang Guan, Kangle Lu, Yiling Lin. Differential distribution patterns and assembly processes of soil microbial communities under contrasting vegetation types at distinctive altitudes in the Changbai Mountain. Frontiers in Microbiology, 2023，14: 1152818.

[25] Yiling Lin., Haitao Wu*, Dandan Liu, Yaxiao Li, Yujuan Kang, Zhongsheng Zhang, Wenfeng Wang. Patterns and drivers of soil surface‐dwelling Oribatida diversity along an altitudinal gradient on the Changbai Mountain, China. Ecology and Evolution, 2023, 13(5), e10105.

[26] Dandan Liu, Haitao Wu*, Hongxian Yu, Dong Liu. Elevation and local habitat characteristics jointly determine soil oribatid mites (Acari: Oribatida) assemblages in the Changbai Mountains, China. Plant and Soil ,2023, 487：485–498。  

[27] Dandan Liu, Dong Liu, D, Hongxian Yu*, Haitao Wu*. Strong variations and shifting mechanisms of altitudal diversity and abundance patterns in soil oribatid mites (Acari: Oribatida) on the Changbai Mountain, China. Applied Soil Ecology, 2023,186, 104808.

[28] Yao Meng, Haitao Wu*, Qiang Guan, Kangle Lu, Yujuan Kang, Guanhua Dai. Responses of riparian insect communities to flow regulation in riverine wetlands of Northeastern China. Hydrobiologia, 2023: 85（18）：3865-3818. 

[29] Kangle Lu, Guangxuan Han, Haitao Wu*. Effects of Spartina alterniflora invasion on the benthic invertebrate community in intertidal wetlands. Ecosphere. 2022, 13:e3963.

[30] Hui Zhang, Xin Sun, Dong Liu, Haitao Wu*, Huai Chen. Air Warming and Drainage Influences Soil Microarthropod Communities. Frontiers in Ecology and Evolution, 2021, 9:731735. 

[31] Dandan Liu, Hongxian Yu, Kangle Lu, Qiang Guan, Haitao Wu*. Freshwater releases into estuarine wetlands change the determinants of benthic invertebrate metacommunity structure. Frontiers in Ecology and Evolution, 2021, 9:721628. 

[32] Kangle Lu, Darold P. Batzer, Haitao Wu*. Aquatic invertebrate assemblages during the spring-thaw season in wetlands of Northeastern China. Hydrobiologia, 2021, 848:3943–3953.

[33] Qiang Guan, Haitao Wu*. Ditches as important aquatic invertebrate habitats: a comparative analysis of their snail (Mollusca: Gastropoda) assemblages with natural wetlands. Aquatic Sciences, 2021, 83 (2):29. 

[34] Wu, H.T. *, Yang, M.Y., Lu, K.L. et al. Effects of Ecological Restoration on Trophic Dynamics in Estuarine Wetlands. Wetlands 41, 10 (2021).

[35] Chuanjing Wu, Haitao Wu*, Dandan Liu, Guangxuan Han, Panpan Zhao, Yujuan Kang. Crab bioturbation significantly alters sediment microbial composition and function in an intertidal marsh. Estuarine, Coastal and Shelf Science, 2021, 249:107116.

[36] Kangle Lu, Haitao Wu*, Qiang Guan, Xianguo Lu. Aquatic invertebrate assemblages as potential indicators of restoration conditions in wetlands of Northeastern China. Restoration Ecology, 2021, 29 (1): e13283.  

[37] Batzer Darold P, Wu Haitao^*. Ecology of terrestrial arthropods in freshwater wetlands. Annual Review of Entomology,2020, 65:101-119. 

[38] Haitao Wu^*, Qiang Guan, Kangle Lu, Guangxuan Han, Baoquan Li, Mengyao Yang. Effects of hydrological connectivity on snail assemblages on the intertidal zone of coastal wetlands. Wetlands, 2020, 40:1627-1634.

[39] WU Haitao^*, LU Kangle, LYU Xianguo, Xue Zhenshan. A Macroinvertebrate Multimetric Index for the Bioassessment of Wetlands Adjacent to Agriculture Fields in the Sanjiang Plain, China. Chinese Geographical Science, 2019, 29(6) :974–984.

[40] Mengyao Yang, Kangle Lu, Darold P Batzer, Haitao Wu*. Freshwater release into estuarine wetlands changes the structure of benthic invertebrate assemblages: A case study from the Yellow River Delta. Science of the Total Environment, 2019, 687:752-758.

[41] Haitao Wu^*, Qiang Guan, Kangle Lu, Darold P. Batzer. Aquatic macroinvertebrate assemblages in wetlands of Northeastern China. Hydrobiologia, 2019, 838（1）:153–162.

[42] Haitao Wu^*, Qiang Guan, Hongyuan Ma, Zhenshan Xue, Mengyao Yang, Darold P. Batzer. Effects of saline conditions and hydrologic permanence on snail assemblages in wetlands of Northeastern China. Ecological Indicators, 2019, 96: 620-627.

[43] KangleLu, Haitao Wu *, Zhenshan Xue, Xianguo Lu, Darold P. Batzer. Development of a multi-metric index based on aquatic invertebrates to assess floodplain wetland condition. Hydrobiologia, 2019, 827:141–153.

[44] Mengyao Yang, Mingzhi Lu, LianxiSheng, Haitao Wu*. Study of the spatial and temporal distribution of accumulated solids in an experimental vertical-flow constructed wetland system. Science of the Total Environment, 2018 (628–629): 509-516. 

[45] Qiang Guan, Jiping Liu, Darold P. Batzer, Xianguo Lu, Haitao Wu*. Snails (Mollusca: Gastropoda) as potential surrogates of overall aquatic invertebrate assemblage in wetlands of Northeastern China. Ecological Indicators, 2018, 90:193-200.

[46] Haitao Wu, Qiang Guan, Xianguo Lu, Darold P. Batzer. Snail (Mollusca:Gastropoda) assemblages as indicators of ecological condition in freshwater wetlands of Northeast China. Ecological Indicators, 2017,75:203-209.

[47] Qiang Guan, Haitao Wu*, Kangle Lu, Xianguo Lu, DaroldP.Batzer. Longitudinal and lateral variation in snail assemblages along a floodplain continuum. Hydrobiologia,2017, 792(1): 345-356. 

[48] Haitao Wu, Mingzhu Lu, Xianguo Lu, Qiang Guan, Xinhua He. Interactions between earthworms and mesofauna has no significant effect on emissions of CO₂ and N₂O from soil. Soil Biology & Biochemistry, 2015, 88: 294-297.

[49] Haitao Wu, XianguoLu,Shouzheng Tong, Darold P Batzer. Soil engineering ants increase CO₂ and N₂O emissions by affecting mound soil physicochemical characteristics from a marsh soil: A laboratory study. Applied Soil Ecology, 2015, 87(3):19-26.

[50] Haitao Wu, Xianguo Lu, Donghui Wu, Lihong Song, Xiumin Yan, Jing Liu. Ant mounds alter spatial and temporal patterns of CO₂, CH₄ and N₂O emissions from a marsh soil. Soil Biology & Biochemistry, 2013, 57:884-891.

[51] Haitao Wu, Darold P Batzer, Xiumin Yan, Donghui Wu, XianguoLu. Contributions of ant mounds to soil carbon and nitrogen pools in a marsh wetland of Northeastern China. Applied Soil Ecology, 2013, 70:9-16.

[52] Haitao Wu, Xianguo Lu, Donghui Wu, XiaominYin.Biogenic structures of two ant species Formica sanguinea and Lasiusflavus altered soil C, N and P distribution in a meadow wetland of the Sanjiang Plain, China. Applied Soil Ecology, 2010, 46(3):321-328.

[53] Wu Haitao, Lu Xianguo, Jiang M. Impacts of soil fauna on litter decomposition at different succession stages of wetland in Sanjiang Plain, China. Chinese Geographical Science, 2009, 19(3):258-264.

[54] Hongyuan Ma, Haoyu Yang, XiaotaoLü, Yuepeng Pan, Haitao Wu*, Zhengwei Liang*, Mark K. J. Ooi. Does high pH give a reliable assessment of the effect of alkaline soil on seed germination? A case study with Leymuschinensis (Poaceae). Plant and Soil, 2015,394(1):35-43.

[55] 武海涛, 姜明, 吕宪国, 毛德华, 神祥金, 王国栋. 湿地保护和修复的基础理论及关键技术问题—第289 期双清论坛. 湿地科学, 2022, 20(1): 128-132.

[56]  祝惠, 武海涛, 邢晓旭, 谢天, 宋长春, 王国栋, 姜明. 中国湿地保护修复成效及发展策略. 中国科学院院刊, 2023, 38(3): 365-375,

[57] 刘丹丹，武海涛*，于洪贤，孙新，刘冬，程鹏，白雪莹，戴冠华，张仲胜，王文锋. 长白山地土壤甲螨和跳虫多样性的海拔梯度格局.地理科学,2023,43(7):1299-1309.

参编著作

[1] 姜明,武海涛,白军红,张明祥,卜兆君,于洪贤,神祥金. 生态学透视:湿地生态学. 高等教育出版社. 2023.

[2] 张明祥,武海涛.水陆过渡-沼泽湿地。2022年，中国林业出版社。

[3] 吕宪国等.《中国湿地研究》.湖南科学出版社.2017年。主编其中4章。

[4] Darold Batzer, Dani Boix. Invertebrates in freshwater wetlands: an international perspective on their ecology, Chapter 7 Peatland invertebrates；Springer International Publishing Switzerland, 2016.

[5] 国家林业局组织编写，《中国湿地资源》(总卷)，负责 第6篇“中国湿地保护与管理”。北京：中国林业出版社，2016。

[6] 傅伯杰主编.《中国主要陆地生态系统服务与生态安全》. 编委. “第14章湿地陆生无脊椎动物多样性与生态过程”，责任作者。北京:高等教育出版社. 2013.

[7] 吕宪国主编.《中国湿地与湿地研究》.石家庄:河北科学出版社出版.2008.第六章“湿地的形成条件”和第十章“东北地区湿地”。

授权专利

[1] 武海涛,马红媛,姜明,吕宪国.一种促进沼泽湿地臌囊苔草种子萌发的方法.专利号：ZL201110129809.0. 2011年授权

[2] 武海涛,刘树元,王云彪,姜明,吕宪国,吴东辉.湿地水样原位连续采样器.专利号：ZL201110225702.6. 2013年授权

[3]武海涛,马红媛,吴东辉, 吕宪国,佟守正.一种促进沼苔草种子萌发的方法.专利号：ZL201110333818.1.2014年授权

[4] 武海涛,吕宪国,王云彪.一种快速高效分离湿地底栖无脊椎动物的方法.专利号：ZL 201310142622.3. 2015年授权

[5] 武海涛,马红媛,王雪峰,王云彪.申请号：一种完全开裂式快捷生态土壤取样器. 专利号：ZL201310110937.X .2015年授权

[6] 武海涛,卢明珠,管强,吕宪国,王云彪. 一种应用于退耕地中土壤动物生态恢复的生物土壤制备方法. ZL201510054605.3. 2017年授权

[7] 武海涛,马红媛,吕宪国,姜明,佟守正,刘波. 一种促进平原区退耕还湿田块地中沼泽植物多样性恢复的方法. ZL201410828630.8 .2017年授权

[8] 武海涛, 马红媛, 刘波，吕宪国.一种利用芦苇根茎移栽重建和恢复退化湿地芦苇植被的方法. ZL201710263270.5. 2019年授权。

[9] 武海涛，张科，马红媛，芦康乐，管强，杨萌尧. 一种退耕还湿田块地快速恢复成东方藨草湿地的方法。ZL 201811250109.5. 2020年授权。

[10] 张科,武海涛,刘吉平,马红媛.一种寒冷区湿地芡实种子萌发及幼苗高效种植方法. ZL 201811109090.2. 2020年授权

[11] 武海涛，张科，马红媛，王深红，康玉娟.一种寒区短瓣金莲花温室直播种植方法.ZL 201910161175.3. 2021年授权

[12] 管强，武海涛，张科，芦康乐，杨萌尧. 放置式湿地水生无脊椎动物采集器及其应用方法. ZL 201810779139.9. 2023年授权

[13]管强，武海涛，芦康乐，张科. 扫刮式草本沼泽湿地水生无脊椎动物采集器及其应用方法。ZL 201910092427.1.2024年授权

[14]赵丹丹,武海涛,刘丹丹. 沼泽湿地生态系统碳储量统计分析系统. ZL 2023 1 0938126.2. 2023年授权

[15]武海涛，管强，康乐，刘丹丹. 一种用于修复湿地的气垫式挖掘作业机. ZL202311189078.8. 2023年授权

[16] 武海涛, 芦康乐, 管强, 刘丹丹, 徐磊, 史家兴.一种多参数湿地复合生境恢复状态智能评估方法. ZL202410965255.5.  2024年授权

[17] 武海涛，刘波，安雨，马红媛，芦康乐，管强，徐磊.一种利用塔头苔草恢复沼泽无脊椎动物种群的方法. ZL202510907451.1. 2025年授权

[18] 武海涛, 刘士琪, 徐磊, 芦康乐, 刘丹丹, 史家兴,杨帆.一种提高苏打盐碱泡沼芡实湿地生产功能的调控方法. ZL202510503910.X. 2025年授权

[19] 刘波,姜明,武海涛,邹元春,佟守正,王梅英,张文广,王国栋,安雨. 促进伴生植物在恢复湿地建植的方法. ZL202410585015.2. 2024年授权

[20] 刘波, 姜明, 王梅英, 武海涛, 张文广, 王国栋, 安雨. 冰沼草种子育苗方法. ZL202410579264.0. 专利申请日：2024年05月11日；授权公告日：2024年09月06日。发明授权.

[21] 薛振山, 张仲胜, 田恩鹏, 武海涛. 一种适于涉禽的深水区生态浮巢. ZL 202410833788.8. 2024年授权.

制定行业和地方标准

[1] 中华人民共和国林业行业标准：湿地生态修复技术规程（LY/T 3353-2023）。武海涛、刘波、安雨、余涛、姜明、吕宪国、崔丽娟、马红媛、张曼胤、齐鹏、管强、林奕伶、刘丹丹、芦康乐、国伟强、薛振山、张仲胜。2023年6月19日发布，2023年11月1日实施。

[2] 吉林省地方标准：湿地调查技术规程（DB 22/T 3242-2021）。中国科学院东北地理与农业生态研究所、吉林省国土资源调查规划研究院。吕宪国、祝占胜、薛振山、刘波、徐春光、武立军、高炳浩、李正东、武海涛、姜明、邹元春、宗翔、杨铎。2021年6月1日发布，2021年6月15日实施。

[3] 吉林省地方标准：重要湿地认定规范（DB 22/T 3174—2020）。中国科学院东北地理与农业生态研究所。本标准起草人：武海涛、刘壮、张仲胜、安雨、郭宝华、刘波、吕宪国、郭岳、高侃、芦康乐。

[4] 吉林省地方标准：沼泽湿地恢复技术规程（DB 22/T 2950-2018）。中国科学院东北地理与农业生态研究所、吉林省环境监测中心站。本标准主要起草人：武海涛、王霞、杨萌尧、管强、姜明、吕宪国。

[5] 黑龙江省地方标准：沼泽湿地大型生物多样性监测技术规程（DB23/T 2083-2018）。中科院东北地理与农业生态研究所，黑龙江省湿地保护管理中心。本标准主要起草人：武海涛、安睿、马红缓、杨萌尧、吕宪国、康铁东、孟什、刘莎莎、胡大慧、张奇、崔迪。

[6] 黑龙江省地方标准：三江平原退耕地湿地恢复技术规程（DB23/T 2385-2019）。中科院东北地理与农业生态研究所，黑龙江省湿地保护管理中心。本标准主要起草人：武海涛、安睿、李险峰、马红媛、佟守正、芦康乐、张科、吕宪国、李楠、陈庆、吕长伟、段延国、田相宜、白成斌。

[7] 黑龙江省地方标准：沼泽生态系统服务价值评估规范（DB23/T 2388-2019）。中科院东北地理与农业生态研究所，黑龙江省湿地保护管理中心。本标准主要起草人：武海涛、安睿、马红媛、李险峰、姜明、芦康乐、张科、陈庆、焉申堂、吕长伟、段延国、田相宜、白成斌。

[8] 吉林省地方标准：湿地生态监测技术规程（DB 22/T 2951-2018）。吉林省环境监测中心站、中国科学院东北地理与农业生态研究所。本标准主要起草人：王霞、武海涛、吴雨华、张丽杰、陶兰、杨萌尧、管强。

[9] 黑龙江省地方标准：沼泽湿地恢复与重建技术规程（DB23/T 2084-2018）。黑龙江省湿地保护管理中心，中科院东北地理与农业生态研究所。本标准主要起草人：安睿、武海涛、康铁东、马红缓、韩勤、白雅溶、杨萌尧、刘莎莎、张奇。

[10] 黑龙江省地方标准：湿地监测技术规程（DB23/T 1816-2016）。第二作者。编制人安睿（黑龙江省湿地保护管理中心），武海涛（中科院东北地理与农业生态研究所）等。

[11] 黑龙江省地方标准：省级湿地公园建设规范（DB23/T 1817-2016）。第二作者。编制人安睿（黑龙江省湿地保护管理中心），武海涛（中科院东北地理与农业生态研究所）等。