Please wait a minute...
img img
高级检索
地球科学进展  2021, Vol. 36 Issue (4): 346-374    DOI: 10.11867/j.issn.1001-8166.2021.038
综述与评述     
20年来我国沉积物环境与污染控制研究进展与展望
范成新1(),刘敏2,王圣瑞3,方红卫4,夏星辉5,曹文志6,丁士明1,侯立军7,王沛芳8,陈敬安9,游静10,王菊英11,盛彦清12,朱伟13
1.中国科学院南京地理与湖泊研究所 湖泊与环境国家重点实验室,江苏 南京 210008
2.地理信息科学教育部重点实验室,华东师范大学 地理科学学院,上海 200240
3.北京师范大学 珠海校区水科学研究中心,粤港水安全保障联合实验室,广东 珠海 519087
4.清华大学 水沙科学与水利水电工程国家重点实验室,北京 100084
5.北京师范大学 水沙科学教育部重点实验室,北京 100875
6.厦门大学 环境与生态学院,福建 厦门 361102
7.华东师范大学 地理科学学院,上海 200240
8.河海大学 浅水湖泊综合治理与;资源开发教育部重点实验室,江苏 南京 210098
9.中国科学院地球化学研究所 环境地球化学国家 重点实验室,贵州 贵阳 550081
10.暨南大学 环境学院,广东 广州 511443
11.国家海洋环境 监测中心 国家环境保护近岸海域生态环境重点实验室,辽宁 大连 266003
12.中国科学院烟台 海岸带研究所 中国科学院海岸带环境过程与生态修复重点实验室,山东 烟台 264003
13.河海大学 环境学院,江苏 南京 210098
Research Progress and Prospect of Sediment Environment and Pollution Control in China in Recent 20 Years
Chengxin FAN1(),Min LIU2,Shengrui WANG3,Hongwei FANG4,Xinghui XIA5,Wenzhi CAO6,Shiming DING1,Lijun HOU7,Peifang WANG8,Jing'an CHEN9,Jing YOU10,Juying WANG11,Yanqing SHENG12,Wei ZHU13
1.State Key Laboratory of Lake Sciences and Environment,Nanjing Institute of Geography and Limnology,Chinese Academy of Sciences,Nanjing 210008,China
2.Key Laboratory of Geographical Information Sciences,Ministry of Education,College of Geographical Sciences,East China Normal University,Shanghai 200240,China
3.Guangdong-Hong Kong Joint Laboratory for Water Security,Research Center of Water Science,Beijing Normal University at Zhuhai,Zhuhai Guangdong 519087,China
4.State Key Laboratory of Hydro-science and Engineering,Tsinghua University,Beijing 100084,China
5.Key Laboratory of Water and Sediment Sciences,Ministry of Education,Beijing Normal University,Beijing 100875,China
6.School of Environment and Ecology,Xiamen University,Xiamen 361102,China
7.College of Geographical Sciences,East China Normal University,Shanghai 200240,China
8.Key Laboratory of Integrated Regulation and Resource Development on Shallow Lakes,Ministry of Education,Hohai University,Nanjing 210098,China
9.State Key Laboratory of Environmental Geochemistry,Institute of Geochemistry,Chinese Academy of Sciences,Guiyang 550081,China
10.School of Environment,Jinan University,Guangzhou 511443,China
11.State Environmental Protection Key Laboratory of Coastal Ecosystem,National Marine Environment Monitoring Center,Dalian 266003,China
12.Key Laboratory of Coastal Environmental Processes and Ecological Remediation,Yantai Institute of Coastal Zone Research,Chinese Academy of Sciences,Yantai Shandong 264003,China
13.College of Environment,Hohai University,Nanjing 210098,China
 全文: PDF(5090 KB)   HTML
摘要:

内陆水体(湖泊、水库、沼泽、河流)和河口海洋等底部,广泛且连续分布着沉积物质,在其形成过程中受自然和人类活动影响,具有与污染物有关的环境意义和特征。中国区域差异大,环境问题较为突出,经过近几十年来围绕沉积物环境和污染控制开展的研究,我国相关成果不断涌现。首先介绍了国际上有关沉积物环境的若干里程碑性研究,回顾了前70年我国沉积物研究的发展历程。然后侧重于与人为活动有关的环境污染,分别从沉积物环境和污染控制修复两个方面,总结和归纳了近20年来中国在沉积物水环境中的作用及效应、污染物在沉积物—水界面环境行为与影响因素、沉积物生态风险与质量基准、污染沉积物的原位修复、污染沉积物疏浚及异位处置利用等方面的主要研究进展,评述了其中一些研究成果的联系和差异。最后对我国沉积物环境研究中存在的问题进行了分析,提出关于多学科交叉、复合污染、新兴/非传统污染物、质量基准、治理技术创新等几个亟需和深入开展研究的科学和技术问题,给出了解决的思路和途径,并进行了展望。

关键词: 沉积物环境效应生态风险质量基准污染控制与修复处理利用中国    
Abstract:

Inland water bodies (lakes, reservoirs, swamps, rivers) and estuarine oceans are widely and continuously distributed with sediments, which are affected by natural and human activities in the process of their formation, and have environmental significance and characteristics related to pollutants. There are great regional differences in China, and the environmental problems are more prominent. After decades of research on sediment environment and pollution control, the relevant achievements in China continue to emerge. This paper first introduces some international landmark studies on sediment environment and reviews the development of sediment research in China in the past 70 years.Then, the main research progress of China in the research fields of sediment environment and pollution control in recent 20 years are systematically summarized, which are the role and effect of sediment in water environment, environmental behavior and influencing factors of pollutants at sediment-water interface, ecological risk and quality criteria of sediments, in-situ remediation of contaminated sediments, environmental dredging and ex-situ disposal as well utilization of contaminated sediments. And the relationship and difference of some research results are reviewed. At the end of the paper, the existing problems of sediment environmental research in China are analyzed, and several scientific and technical problems that need to be studied urgently and deeply, such as interdisciplinary, composite pollution, emerging/non-traditional pollutants, quality criteria, and governance technology innovation, are put forward. The solutions and approaches are proposed, and the prospects are also given.

Key words: Sediment    Environmental effects    Ecological risk    Quality criteria    Pollution control and remediation    Treatment and utilization    China.
收稿日期: 2020-10-15 出版日期: 2021-05-31
ZTFLH:  P951  
基金资助: 国家自然科学基金重点项目“长江三角洲城市群典型POPs环境过程、耦合机理与空间模拟”(41730646);国家自然科学基金联合基金项目“洱海界面系统磷迁移转化特征及藻类水华影响机制”(U1902207);国家自然科学基金重大研究计划重点支持项目“径流变化条件下雅鲁藏布江生源物质迁移转化过程及微生物作用机制”(91647206);“径流变化条件下雅鲁藏布江水沙变化及河床演变研究”(91647210)
作者简介: 范成新(1954-),男,江苏南京人,研究员,主要从事湖河沉积物污染及其修复研究. E-mail:cxfan@niglas.ac.cn
服务  
把本文推荐给朋友
加入引用管理器
E-mail Alert
RSS
作者相关文章  
范成新
刘敏
王圣瑞
方红卫
夏星辉
曹文志
丁士明
侯立军
王沛芳
陈敬安
游静
王菊英
盛彦清
朱伟

引用本文:

范成新,刘敏,王圣瑞,方红卫,夏星辉,曹文志,丁士明,侯立军,王沛芳,陈敬安,游静,王菊英,盛彦清,朱伟. 近20年来我国沉积物环境与污染控制研究进展与展望[J]. 地球科学进展, 2021, 36(4): 346-374.

Chengxin FAN,Min LIU,Shengrui WANG,Hongwei FANG,Xinghui XIA,Wenzhi CAO,Shiming DING,Lijun HOU,Peifang WANG,Jing'an CHEN,Jing YOU,Juying WANG,Yanqing SHENG,Wei ZHU. Research Progress and Prospect of Sediment Environment and Pollution Control in China in Recent 20 Years. Advances in Earth Science, 2021, 36(4): 346-374.

链接本文:

http://www.adearth.ac.cn/CN/10.11867/j.issn.1001-8166.2021.038        http://www.adearth.ac.cn/CN/Y2021/V36/I4/346

图1  沉积物在河口关键带物质循环中的作用示意图
图2  藻类水华与磷的生物地球化学过程DRP:溶解性活性磷;DOP:溶解性有机磷
污染物无效应数据列有效应数据列TELPEL
CN50CN85Cy15Cy50
As/(mg/kg)14.2027.129.20156.6020.4065.14
Cd/(mg/kg)2.022.605.4428.143.318.55
Cr/(mg/kg)40.6050.5056.40594.9047.80128.60
Cu/(mg/kg)26.0032.3049.50225.1035.9085.30
Hg/(mg/kg)0.881.453.1928.201.676.39
Pb/(mg/kg)46.9060.8056.10265.4051.30127.03
Zn/(mg/kg)147.0021.20239.70723.40187.70391.60
硫化物/(mg/kg)169.80316.00496.001 090.00290.20586.90
有机质/%1.442.352.923.352.052.81
油类/(mg/kg)250.41660.90780.601 445.80442.10977.50
DDT/(mg/kg)0.0210.0370.0340.0580.0280.047
六六六/(mg/kg)0.020.0280.0330.170.0260.069
表1  海洋沉积物质量基准的求算结果[189]
图3  我国研发的环保疏浚深度确定方法及疏浚后新生表层的形成过程意图x:含量;RI:风险指数;R:释放速率;EC0:Critical Equilibrium Concentration;xˉ+nσ:含量的平均值加n个标准偏差σ,其中n为自然数;h:污染深度;A:视觉分层法;B:拐点法;C:背景值法;D:频率控制法;E:标准偏差倍数法;F:生态风险指数法;G:分层释放法;H:吸附解析法
1 HALES S, ADEE S. VII. An examination of the strength of several of the principal purging waters, especially of that of Jessop's well; by the Rev. Stephen Hales DD & FRS communicated in a letter to Cromwell Mortimer MD Secr. RS with a letter from Swithin Adee MDFRS to Dr. Hales, on the virtues of the said well[J]. Philosophical Transactions of the Royal Society of London, 1750, 46(495): 446-451.
2 BAUER F. XII. Some experiments on the fungi which constitute the colouring matter of the red snow discovered in Baffin's Bay. By Francis Bauer, Esq. F. L. S. In a letter addressed to the Right Honourable Sir Joseph Banks, Bart. G. C. B. P. R. S. &c. &c[J]. Philosophical Transactions of the Royal Society of London, 1820,110:165-173.
3 KANE R J. IV. On the composition of the urine and blood in diabetes mellitus[J]. The Dublin Journal of Medical and Chemical Science, 1832, 1(1): 15-24.
4 ANDREWS E B. Bituminous coal: Its origin, varieties and a few of its special uses[J]. Journal of the Franklin Institute,1873,95(1):58-69.
5 FRAZER P. Notes on two traps: A case of alteration of earthy sediments[J]. Proceedings of the Academy of Natural Sciences of Philadelphia, 1876,28:60.
6 RITTENBERG S C, EMERY K O, ORR W L. Regeneration of nutrients in sediments of marine basins[J]. Deep Sea Research,1955, 3(1):23-45.
7 OLIFF W D,BERRISFORD C D, TURNER W D, et al. The ecology and chemistry of sandy beaches and nearshore submarine sediments of Natal—II: Pollution criteria for nearshore sediments of the Natal coast[J]. Water Research,1967,1(2): 131-146.
8 WOODIN S A. Polychaete abundance patterns in a marine soft-sediment environment: The importance of biological interactions[J]. Ecological Monographs, 1974,44(2):171-187.
9 HESSLEIN R H. An in situ sampler for close interval pore water studies[J]. Limnology and Oceanography, 1976, 21(6): 912-914.
10 DAVISON W, ZHANG Hao. In situ speciation measurements of trace components in natural waters using thin-film gels[J]. Nature, 1994, 367(6 463): 546-548.
11 MCD.TOWNSEND C. 1 The effect of levees on the flow of sediment in rivers. A Discussion of the Article on "The Huai River Conservancy Project"[R]. Professional Memoirs, Corps of Engineers, United States Army, and Engineer Department at Large,1915,7(32):181-190.
12 WONG Wenhao. Sediments of the north china rivers and their geological significance or a quantitative study of the phenomena of erosion and deposition in North China[J]. Bulletin of the Geological Society of China, 1931, 10(1): 247-272.
13 MA Rongzhi. Influence of geology on soil near Weiyuan, Sichuan Province[J]. Chinese Journal of Geological Review,1940(6):521-532.
13 馬溶之. 四川威遠附近地質對土壤之影響[J] . 地质论评,1940(6):521-532.
14 XIONG Yi. Properties and formation of Pleistocene clay in Jiangxi Province[J].Chinese Journal of Geological Review, 1944():109-120.
14 熊毅.江西更新统黏土之性质及其生成,地质论评,1944():109-120.
15 REN Meie. New research on the Yellow River in China[J]. Acta geographica Sinica,1948, 15(1): 31-33.
15 任美锷. 我国最近对于黄河问题之新研究[J].地理学报, 1948, 15(1): 31-33.
16 ZHANG Hanying. On the root cause of the Yellow River[J]. New Yellow River, 1949(00):32-36.
16 张含英.黄河治本论[J].新黄河, 1949(00):32-36.
17 CAI Shutang. Precipitating movement of sediment in still water[J]. Acta Physica Sinica, 1956(5):402-418.
17 蔡树棠.泥沙在静水中的沉淀运动[J].物理学报, 1956(5):402-418.
18 QIAN Ning. Sediment problems in rivers[M]. Beijing:Science Popularization Press, 1957.
18 钱宁.河流中的泥沙问题[M].北京:科学普及出版社,1957.
19 XIE Jianheng. On the riverbed evolution of the Lower Yellow River(second half)[J]. Yellow River Construction, 1957(7):19-23.
19 谢鉴衡.关于黄河下游河床演变问题(下)[J].黄河建设,1957(7):19-23.
20 Qiaowei MAI. Sediment problem of Sanmenxia Hydro Junction[J]. New Yellow River, 1955(11):50-57.
20 麦乔威.三门峡水力枢纽的泥沙问题[J].新黄河,1955(11):50-57.
21 ZHAO Jinsheng. Sediment movement of sandy coast, port site selection and erosion and deposition prevention measures[J].Chinese Journal of Port Engineering Technology Communication, 1975(6):1-36.
21 赵今声.沙质海岸的泥沙运动,港址选择和防冲防淤措施[J].港工技术通讯,1975(6):1-36.
22 XIONG Yi, XI Chengfan. Characteristics and evolution of Quaternary sediments in North China Plain[J]. Science Bulletin,1957(6):173-174.
22 熊毅,席承藩.华北平原第四纪沉积物的性质及其演变[J].科学通报, 1957(6):173-174.
23 FAN Shiqing, QIN Yunshan. A preliminary study on sediment in the East China Sea and the Southern Yellow Sea[J]. Chinese Journal of Oceanology and Limnology, 1959(2):82-85.
23 范时清,秦蕴珊,中国东海和黄海南部底质的初步研究[J].海洋与湖沼, 1959(2):82-85.
24 Nanjing Institute of Geography, Chinese Academy of Sciences. Preliminary report on comprehensive investigation of Lake Taihu [M]. Beijing: Science Press, 1965.
24 中国科学院南京地理研究所. 太湖综合调查初步报告[M].北京:科学出版社,1965.
25 HUANG Difan, CHEN Kezao, XU Yongchang, et al. The formation of asphalts in Quaternary sediments of Qinghai Lake and the origin of continental petroleum[J]. Acta Geologica Sinica, 1964(2):171-190.
25 黄第藩,陈克造,徐永昌,等.青海湖第四紀沉积物中瀝青的形成与陆相石油成因問题[J].地质学报,1964(2):171-190.
26 CHEN Jiyu,YUN Caixing, XU Haigen, et al. The developmental model of the Changjiang River Estuary during last 2000 years [J]. Acta Oceanologia Sinica,1979(1):103-111.
26 陈吉余,恽才兴,徐海根,等.两千年来长江河口发育的模式[J].海洋学报, 1979(1):103-111.
27 WANG Sumin, LI Jianren. Lacustrine sedimentation: An effective method to study the historical climate: A case study of Qinghai Lake and Daihai Lake[J]. Science Bulletin,1991(1):54-56.
27 王苏民,李建仁.湖泊沉积——研究历史气候的有效手段——以青海湖、岱海为例[J].科学通报,1991(1):54-56.
28 WAN Guojiang, HUANG Ronggui, WANG Changsheng, et al. The variation of 210Poex vertical profile at the top of Hongfeng Lake[J]. Science Bulletin,1990(8):612-615.
28 万国江,黄荣贵,王长生,等.红枫湖沉积物顶部210Poex垂直剖面的变异[J].科学通报,1990(8):612-615.
29 ZHANG Licheng, DONG Wenjiang, ZHENG Jianxun, et al. The metal form and form factors of heavy metals in the Xiangjiang River sediments[J]. Acta Geographica Sinica, 1983(1):55-64.
29 张立成,董文江,郑建勋,等.湘江河流沉积物重金属的形态类型及其形成因素[J].地理学报,1983(1):55-64.
30 GUO Laodong, HONG Huasheng, ZHUANG Jihao. Sediment-water exchange of phosphorus and silicon in Luoyuan Bay, East Fujian[J]. Chinese Journal of Tropical Ocean, 1989(3):60-67.
30 郭劳动,洪华生,庄继浩. 闽东罗源湾沉积物—水界面磷、硅的交换[J].热带海洋,1989(3):60-67.
31 CHEN Shuitu, RUAN Wuqi. Biogeochemistry of phosphorus in Jiulong River Estuary and Western sea area of Xiamen, Ⅱ. Distribution of phosphorus forms in surface sediments and their transformation in resuspension[J]. Acta Oceanologica Sinica, 1993,15(6):47-54.
31 陈水土,阮五崎.九龙江口、厦门西海域磷的生物地球化学研究,Ⅱ.表层沉积物中磷形态的分布及在再悬浮中的转化[J].海洋学报,1993,15(6):47-54.
32 WANG Tingjian, SU Rui, JIN Xiangcan, et al. The effect to water quality of phosphorus loading and its release in the sediments of urban eutrophic lakes [J]. Chinese Journal of Environmental Science Research, 1994,7(4):12-19.
32 王庭健,苏睿,金相灿,等.城市富营养湖泊沉积物中磷负荷及其释放对水质的影响[J].环境科学研究,1994,7(4):12-19.
33 WANG Xiaorong, HUA Zhaozhe, XU Ling, et al. The effects of the environmental conditions on phosphorus release in lake sediments[J]. Chinese Journal of Environmental Chemistry,1996(1):15-19.
33 王晓蓉,华兆哲,徐菱,等.环境条件变化对太湖沉积物磷释放的影响[J].环境化学,1996(1):15-19.
34 XIANG Mingju, SHI Jiyang, ZHOU Youping, et al. The distribution and evolution of fatty acids in various sediments and its significance[J]. Acta Sedimentologica Sinica,1997(2):84-88.
34 向明菊,史继扬,周友平,等.不同类型沉积物中脂肪酸的分布、演化和生烃意义[J].沉积学报,1997(2):84-88.
35 SONG Jinming. Chemistry of sediment seawater interface in offshore China[M]. Beijing:China Ocean Press,1997:222.
35 宋金明.中国近海沉积物—海水界面化学[M].海洋出版社,1997:222.
36 YU Zishan, WANG Shihong. The effect of bioturbation of Nuttallia olivacea (Jay,1857) on the vertical distribution of sediment particles[J]. Journal of Qingdao Ocean University (Natural Science Edition), 1999,29(2): 279-282.
36 于子山,王诗红. 紫彩血蛤的生物扰动对沉积物颗粒垂直分布的影响[J]. 青岛海洋大学学报:自然科学版, 1999,29(2): 279-282.
37 HONG Yetang, PIAO Hechun, JIANG Hongbo. Environmental geological characteristics of sediment in the Yellow River[J]. Chinese Science (Part B),1990(11):1 175-1 184.
37 洪业汤,朴河春,姜洪波.黄河泥沙的环境地质特征[J].中国科学:B辑,1990(11):1 175-1 184.
38 FAN Chengxin, ZHOU Yiyong, WU Qinglong. The sediment-water interface of lakes: Processes and effects[M]. Beijing: Science Press, 2013: 104-111,175-184,244-247,302-349.
38 范成新, 周易勇, 吴庆龙. 湖泊沉积物界面过程与效应[M]. 北京: 科学出版社, 2013: 104-111,175-184,244-247,302-349.
39 LIU Min, XU Shiyuan, HOU Lijun, et al. Environmental Biogeochemical processes of Nutrients at the sediment-water interface of tidal flat in the Yangtze Estuary[M]. Beijing: Science Press,2007.
39 刘敏,许世远,侯立军,等.长江口潮滩沉积物—水界面营养盐环境生物地球化学过程[M]. 北京:科学出版社,2007.
40 WANG Shengrui. Biogeochemistry of Nitrogen and Phosphorus in lake sediment-water interface processes[M]. Beijing: Science Press,2013.
40 王圣瑞. 湖泊沉积物—水界面过程氮磷生物地球化学[M].北京:科学出版社,2013.
41 WEN Xuefa, ZHANG Xinyu, WEI Jie, et al. Understanding the biogeochemical process and mechanism of ecosystem carbon cycle from the perspective of the Earth's critical zone[J]. Advances in Earth Science, 2019, 34(5): 471-479.
41 温学发, 张心昱, 魏杰, 等. 地球关键带视角理解生态系统碳生物地球化学过程与机制[J]. 地球科学进展, 2019, 34(5): 471-479.
42 JI Na, CHENG Heqin, YANG Zhongyong, et al. Sedimentary and morphological evolution of nearshore coast of Yangtze Estuary in the last 30 years[J]. Acta Geographica Sinica, 2013, 68(7): 945-954.
42 计娜, 程和琴, 杨忠勇, 等. 近30年来长江口岸滩沉积物与地貌演变特征[J]. 地理学报, 2013, 68(7): 945-954.
43 Lü Ying, CHEN Fanrong, YANG Yongqiang, et al. Study on profile distribution of nutrients and exchange fluxes at sediment-water interface in inner Pearl River Estuary in spring[J]. Chinese Journal of Earth and Environment, 2006, 34(4): 1-6.
43 吕莹, 陈繁荣, 杨永强, 等. 春季珠江口内营养盐剖面分布和沉积物—水界面交换通量的研究[J]. 地球与环境, 2006, 34(4): 1-6.
44 SUN Jiao, YUAN Dekui, FENG Huan, et al. Research progress on exchange fluxes of nutrients in sediment-water interface [J]. Marine Environmental Science, 2012, 31(6): 933-938.
44 孙娇, 袁德奎, 冯桓, 等. 沉积物—水界面营养盐交换通量的研究进展[J]. 海洋环境科学, 2012, 31(6): 933-938.
45 LIN Xianbiao, LIU Min, HOU Lijun, et al. Nitrogen losses in sediments of the East China Sea: Spatiotemporal variations, controlling factors, and environmental implications[J]. Journal of Geophysical Research: Biogeosciences, 2017, 122(10): 2 699-2 715.
46 LIU Min, XU Shiyuan. Environmental biogeochemical process and ecological risk of POPs in tidal flat of Yangtze River Estuary[M]. Beijing: Chinese Environmental Science Press,2005.
46 刘敏,许世远. 长江口潮滩POPs环境生物地球化学过程与生态风险[M]. 北京:中国环境科学出版社,2005.
47 Lü Min, LUAN Xiaolin, LIAO Chunyang, et al. Human impacts on polycyclic aromatic hydrocarbon distribution in chinese intertidal zones[J]. Nature Sustainability, 2020,3:878-884.
48 YANG Z, WANG H, SAITO Y. Dam impacts on the Changjiang (Yangtze) River sediment discharge to the sea: The past 55 years and after the Three Gorges Dam[J]. Water Resources Research,2006,42(4): 501-517.
49 WANG Shuai, FU Bojie, PIAO Shilong, et al. Reduced sediment transport in the Yellow River due to anthropogenic changes[J]. Nature Geoscience,2020,9: 38-41.
50 WU Chuangshou, YANG S L, LEI Y P. Quantifying the anthropogenic and climatic impacts on water discharge and sediment load in the Pearl River (Zhujiang), China (1954-2009)[J]. Journal of Hydrology, 2012,452/453: 190-204.
51 LIU Wei, WANG Suiji. Temporal and spatial change of the sedimentation rate on the channel cross-sections in the lower reaches of Yellow River and its influence factors[J]. Chinese Journal of Soil and Water Conservation Research, 2019,26(2): 167-174.
51 刘慰, 王随继.黄河下游河道断面沉积速率的时段变化及其原因分析[J]. 水土保持研究, 2019,26(2): 167-174.
52 WANG Houjie, YANG Zuosheng, BI Naishuang, et al. The rapid swing of the mainstream of the estuary into the sea during the Yellow River water and sediment regulation in 2005[J]. Chinese Science Bulletin, 2005(23): 2 656-2 662.
52 王厚杰,杨作升,毕乃双,等. 2005年黄河调水调沙期间河口入海主流的快速摆动[J].科学通报, 2005(23):2 656-2 662.
53 YANG Yunping, LI Yitian, SUN Zhaohua, et al. Surface sediment in the nearby shelf of the Yangtze River: Change and causes[J]. Acta Sedimentologica Sinica,2014,32(5): 863-872.
53 杨云平, 李义天, 孙昭华, 等. 长江口邻近陆架表层沉积物变化特征及成因[J].沉积学报, 2014,32(5): 863-872.
54 CHAI Chao, YU Zhiming, SHEN Zhiliang, et al. Nutrient characteristics in the Yangtze River Estuary and the adjacent East China Sea before and after impoundment of the Three Gorges Dam[J]. Science of the Total Environment, 2009, 407(16): 4 687-4 695.
55 ZHANG Shuo, JIAN Xing, ZHANG Wei. Sedimentary Provenance analysis using detrital apatite: A review[J]. Advances in Earth Science, 2018,33(11):1 142-1 153.
55 张硕,简星,张巍. 碎屑磷灰石对沉积物源判别的指示[J].地球科学进展, 2018,33(11):1 142-1 153.
56 WU Gaijie, CAO Wenzhi, WANG, Feifei, et al. Riverine nutrient fluxes and environmental effects on China's estuaries[J]. Science of the Total Environment, 2019,661: 130-137.
57 XU Yayan, SONG Jinming, LI Xuegang, et al. Distribution characteristics and ecological risk assessment of heavy metals in surface sediments of Bohai Bay[J]. Chinese Journal of Environmental science, 2012,33(3): 732-740.
57 徐亚岩, 宋金明, 李学刚,等.渤海湾表层沉积物各形态重金属的分布特征与生态风险评价[J]. 环境科学, 2012,33(3): 732-740.
58 Bixian MAI, FU Jiamo, ZHANG Gan, et al. Polycyclic aromatic hydrocarbons in sediments from the Pearl river and estuary, China: Spatial and temporal distribution and sources[J].Applied Geochemistry,2001,1611/120: 1 429-1 445.
59 SHI Hao, YANG Yi, LIU Min, et al. Occurrence and distribution of antibiotics in the surface sediments of the Yangtze Estuary and nearby coastal areas[J]. Marine Pollution Bulletin, 2014,83(1): 317-323.
60 HUANG Honghui, LIN Yantang, LI Chunhou, et al. Ecology study on the Benthic Animals of Pearl River Estuary[J]. Acta Ecologica Sinica, 2002(4): 603-607.
60 黄洪辉,林燕棠,李纯厚,等.珠江口底栖动物生态学研究[J]. 生态学报, 2002(4): 603-607.
61 SUN M Y, DAFFORN K A, BROWN M V, et al. Bacterial communities are sensitive indicators of contaminant stress[J]. Marine Pollution Bulletin, 2012 ,64(5): 1 029-1 038.
62 MENG Xiangliang, JIANG Xiaoming, LI Zhengfei, et al. Responses of macroinvertebrates and local environment to short-term commercial sand dredging practices in a flood-plain lake[J]. Science of the Total Environment, 2018,631/632:1 350-1 359.
63 MENG Xiangliang, CHEN Juanjuan, Li Zhengfei, et al. Degraded functional structure of macroinvertebrates caused by commercial sand dredging practices in a flood plain lake[J]. Environmental Pollution, 2020, 263(Part B): 114415.
64 LI Xiubao, HUANG Hui, LIAN Jiansheng. Coral community changes in response to a high sedimentation event: A case study in southern Hainan Island[J]. Chinese Science Bulletin, 2012,58(9):1 028-1 037.
65 QIAN Ning, WAN Zhaohui. Dynamics of sediment movement[M]. Beijing: Science Press, 2003: 15-20.
65 钱宁, 万兆惠. 泥沙运动力学[M]. 北京: 科学出版社, 2003: 15-20.
66 FANG Hongwei, CHEN Minghong, CHEN Zhihe. Surface characteristics and model of environmental sediments[M]. Beijing: Science Press,2009.
66 方红卫, 陈明洪, 陈志和. 环境泥沙的表面特性与模型[M]. 北京: 科学出版社,2009.
67 TANG Hongxiao, QIAN Yi, WEN Xianghua. Characteristics and control principles of water particles and refractory organic matter (Volume I): Water particles[M]. Beijing: Chinese Environmental Science Press, 2000.
67 汤鸿霄, 钱易, 文湘华. 水体颗粒物和难降解有机物的特性与控制技术原理(上卷):水体颗粒物[M]. 北京: 中国环境科学出版社, 2000.
68 XIAO Yang, LU Qi, CHENG Haoke, et al. Surface properties of sediments and its effect on phosphorus adsorption[J]. Chinese Journal of Sediment Research,2011(6): 64-68.
68 肖洋, 陆奇, 成浩科,等. 泥沙表面特性及其对磷吸附的影响[J]. 泥沙研究,2011(6): 64-68.
69 CHEN Minghong, FANG Hongwei, CHEN Zhihe. Experiment of phosphorus distribution on sediment surface[J]. Chinese Journal of Sediment Research, 2009(4): 51-57.
69 陈明洪,方红卫,陈志和.泥沙颗粒表面磷吸附分布的实验研究[J].泥沙研究,2009(4):51-57.
70 FANG Hongwei, HUANG Lei, ZHAO Huiming, et al. Mechanics of bio-sediment transport[M]. Berlin: Springer, 2020.
71 CHEN Xindi, ZHANG Changkuan, ZHOU Zeng, et al. Stabilizing effects of bacterial biofilms: EPS penetration and redistribution of bed stability down the sediment profile[J]. Journal of Geophysical Research: Biogeosciences, 2017,122: 3 113-3 125.
72 LI Yi, WANG Chao, ZHANG Wenlong, et al. Modelling the effects of hydrodynamic regimes on microbial communities within fluvial biofilms: Combining deterministic and stochastic processes[J]. Environmental Science & Technology,2015, 49: 12 869-12 878.
73 YANG Shouye, YIN Ping. Sediment source-to-sink processes of small mountainous rivers under the impacts of natural environme changes and human activities[J]. Marine Geology and Quaternary Geology, 2018,38(1): 1-10.
73 杨守业,印萍.自然环境变化与人类活动影响下的中小河流沉积物源汇过程[J].海洋地质与第四纪地质, 2018,38(1):1-10.
74 FAN Chengxin, ZHANG Lu, QIN Boqiang, et al. Migration mechanism of biogenic elements and their quantification on the sediment-water interface of Lake Taihu: I. Spatial variation of the ammonium release rates and its source and sink fluxes[J]. Chinese Journal of Lake Science, 2004(1): 10-20.
74 范成新,张路,秦伯强,等.太湖沉积物—水界面生源要素迁移机制及定量化——1.铵态氮释放速率的空间差异及源—汇通量[J].湖泊科学,2004(1):10-20.
75 FAN Chengxin, ZHANG Lu, BAO Xianming, et al. Migration mechanism of biogenic elements and their quantification on the sediment-water interface of Lake Taihu:II.chemical thermodynamic mechanism of phosphorus release and its source-sink transition[J]. Chinese Journal of Lake Science, 2006(3): 207-217.
75 范成新,张路,包先明,等.太湖沉积物—水界面生源要素迁移机制及定量化——2.磷释放的热力学机制及源—汇转换[J].湖泊科学,2006(3):207-217.
76 ZHANG Yakun, YANG Libiao, LEI Kun, et al. Exchange and deposition fluxes of nitrogen and phosphorus across sediment-water interface in lower Yellow River[J]. Sediment Research, 2013(6): 66-
76 74[张亚昆,杨丽标,雷坤,等.黄河下游沉积物—水界面氮磷交换与沉积通量研究[J].泥沙研究, 2013(6):66-74.]
77 WANG Houjie, YUAN Xiaojun, WANG Yan, et al. Evolution of the abandoned Shenxiangou-Diaokou delta lobe: Processes and mechanism[J]. Sediment Research, 2010(4): 51-60.
77 王厚杰,原晓军,王燕,等.现代黄河三角洲废弃神仙沟—钓口叶瓣的演化及其动力机制[J].泥沙研究, 2010(4):51-60.
78 DONG Aiguo. Source, sink and its environmental record of sediments in Yellow Sea and East China Sea [D]. Qingdao: Ocean University of China, 2011.
78 董爱国.黄、东海海域沉积物的源汇效应及其环境意义[D].青岛:中国海洋大学, 2011.
79 SONG Jinming, QU Baoxiao, LI Xuegang, et al. Carbon sinks/sources in the Yellow and East China Seas—Air-sea interface exchange, dissolution in seawater, and burial in sediments[J]. Science China Earth Sciences, 2018, 61(11):1 583-1 593.
79 宋金明,曲宝晓,李学刚,等.黄东海的碳源汇:大气交换、水体溶存与沉积物埋藏[J].中国科学:D辑, 2018, 48(11): 1 444-1 455.
80 DING Shiming, CHEN Musong, GONG Mengdan, et al. Internal phosphorus loading from sediments causes seasonal nitrogen limitation for harmful algal blooms[J]. Science of the Total Environment, 2018, 625: 872-884.
81 YANG Zhihong. A study on phosphorus flux from sediment in reservoirs: A case study of Xinshan Reservoir and Shimen Reservoir [D]. Taiwan:Taiwan University, 2007.
81 楊智閎.水庫底泥磷通量之研究——以新山水庫、石門水庫為例[D].台湾:台湾大學, 2007.
82 WANG Jingfu, CHEN Jingan, LUO Jing, et al. Comparative study on quantitative estimations of phosphorus release flux from sediments of Lake Hongfeng, Guizhou Province, China[J]. Earth and Environment, 2018, 46(1): 1-6.
82 王敬富, 陈敬安, 罗婧, 等. 红枫湖沉积物内源磷释放通量估算方法的对比研究[J]. 地球与环境, 2018, 46(1): 1-6.
83 FAN Chengxin, ZHANG Lu, QIN Boqiang, et al. Estimation on dynamic release of phosphorus from wind-induced suspended particulate matter in Lake Taihu [J]. Science in China (Series D), 2003,33(8): 760-768.
83 范成新,张路,秦伯强,等. 风浪作用下太湖悬浮态颗粒物中磷的动态释放估算[J]. 中国科学:D辑,2003,33(8): 760-768.
84 QIN Boqiang, HU Weiping, GAO Guang, et al. Dynamics of sediment resuspension and the conceptual schema of nutrient release in the large shallow Lake Taihu,China[J]. Chinese Science Bulletin,2004,49(1): 54-64.
84 秦伯强,胡维平,高光,等.太湖沉积物悬浮的动力机制及内源释放的概念性模式[J].科学通报,2003,48(l7):1 822-1 831.
85 QIN Boqiang, ZHU Guangwei, ZHANG Lu, et al. Estimation of internal nutrient release in large shallow Lake Taihu, China[J]. Science in China(Series D),2006,49():33-44.
85 秦伯强,朱广伟,张路,等.大型浅水湖泊沉积物内源营养盐释放模式及其估算方法——以太湖为例[J].中国科学:D辑,2005,35():33-44.
86 LUO Liancong, QIN Boqiang, ZHU Guangwei. Calculation of total and resuspendable sediment volume in Lake Taihu[J]. Oceanology et Limnoloia Sinica, 2004,35(6): 491-496.
86 罗潋葱,秦伯强,朱广伟.太湖底泥蓄积量和可悬浮量的计算[J].海洋与湖沼,2004,35(6):491-496.
87 PANG Yong, YAN Runrun, YU Zhongbo, et al. Suspension-sedimentation of sediment and release amount of internal load in Lake Taihu affected by wind[J]. Chinese Journal of Environmental Science, 2008(9): 2 456-2 464.
87 逄勇,颜润润,余钟波,等.风浪作用下的底泥悬浮沉降及内源释放量研究[J].环境科学, 2008(9):2 456-2 464.
88 PANG Yong, YAN Runrun, LI Yiping, et al. Contribution of combined action of exogenous source and internal load on water nutrient in Taihu Lake[J]. Chinese Journal of Water Conservancy, 2008(9): 1 051-1 059.
88 逄勇,颜润润,李一平,等.内外源共同作用对太湖营养盐贡献量研究[J].水利学报,2008(9):1 051-1 059.
89 FAN Chengxin. Advances and prospect in sediment-water interface of lakes:A review[J]. Lake Sciences, 2019,31(5): 1 191-1 218.
89 范成新.湖泊沉积物—水界面研究进展与展望[J].湖泊科学,2019,31(5):1 191-1 218.
90 HOU Lijun, YIN Guoyu, LIU Min, et al. Effects of sulfamethazine on denitrification and the associated N2O release in estuarine and coastal sediments[J]. Environmental Science & Technology, 2015, 49(1): 326-333.
91 LEI Yang, WANG Peifang, WANG Chao, et al. The effect of submerged plants on the release of heavy metals from sediment under different hydrodynamic disturbances[J]. Hydrodynamic Research and Progress(A), 2015,30(3): 245-250.
91 雷阳,王沛芳,王超,等.不同水动力扰动下沉水植物对沉积物重金属释放的影响[J].水动力学研究与进展A辑,2015,30(3):245-250.
92 CHENG Haomiao, HUA Zulin. Effects of hydrodynamic disturbances and resuspension characteristics on the release of tetrabromobisphenol A from sediment [J]. Environment Pollution, 2016, 219: 785-793.
93 SHI Dan, DING Shiming, XU Di, et al. Determination of soluble reactive phosphorus in porewaters of sediments using the technique of diffusive equilibration in thin films[J]. Journal of Lake Sciences, 2009,21(6):768-774.
93 时丹, 丁士明, 许笛,等. 利用薄膜扩散平衡技术分析沉积物间隙水溶解态反应性磷[J]. 湖泊科学, 2009,21(6):768-774.
94 LUO Min, HUANG Jiafang, ZHU Wenfeng, et al. Impacts of increasing salinity and inundation on rates and pathways of organic carbon mineralization in tidal wetlands: A review[J]. Hydrobiologia, 2019, 827(1): 31-49.]
95 PAN Feng, GUO Zhanrong, LIU Huatai, et al. High-resolution distribution and biogeochemical behavior of phosphorus and iron at sediment-water interface of tidal flat[J]. Geosciences, 2018,43(11): 4 109-4 119.
95 潘峰,郭占荣,刘花台,等.潮滩沉积物—水界面磷、铁的高分辨率分布特征及生物地球化学行为[J]. 地球科学, 2018,43(11):4 109-4 119.
96 DING Shiming, XU Di, SUN Qin, et al. Measurement of dissolved reactive phosphorus using the diffusive gradients in thin films technique with a high-capacity binding phase[J]. Environmental Science and Technology, 2010, 44: 8 169-8 174.
97 DING Shiming, SUN Qin, XU Di, et al. High-resolution simultaneous measurements of dissolved reactive phosphorus and dissolved sulfide: The first observation of their simultaneous release in sediments[J]. Environmental Science and Technology, 2012,46: 8 297-8 304.
98 ZHANG Yaohong, WANG Lin, XIE Xiaojin, et al. Effects of invasion of Spartina alterniflora and exogenous N deposition on N2O emissions in a coastal salt marsh[J]. Ecological Engineering, 2013, 58: 77-83.
99 SHENG Qiang, ZHAO Bin, HUANG Mingyao, et al. Greenhouse gas emissions following an invasive plant eradication program[J]. Ecological Engineering, 2014,73:229-237.
100 XIE Xuefeng, SUN Xiaomin, WU Tao, et al. Impacts of spartina alterniflora invasion on coastal wetland ecosystem: Advances and prospects[J]. Chinese Journal of Applied Ecology, 2020, 31(6): 2 119-2 128.
100 解雪峰, 孙晓敏, 吴涛, 等. 互花米草入侵对滨海湿地生态系统的影响研究进展[J]. 应用生态学报, 2020, 31(6): 2 119-2 128.
101 YOU Bensheng, ZHONG Jicheng,FAN Chengxin, et al. Effects of hydrodynamics processes on phosphorus fluxes from sediment in large, shallow Taihu Lake[J]. Journal of Environmental Sciences,2007,19(9):1 055-1 060.
102 TIAN Zhuangcai, GUO Xiujun, YU Le, et al. Review of seabed sediment resuspension by internal solitary wave[J]. Advances in Earth Science,2018,33(2):166-178.
102 田壮才,郭秀军,余乐,等.内孤立波悬浮海底沉积物研究进展[J]. 地球科学进展,2018,33(2):166-178.
103 ZHENG Shasha, WANG Peifang, WANG Chao, et al.Sediment resuspension under action of wind in Taihu Lake,China[J]. International Journal of SedimentResearch,2015,30(1): 48-62.
104 DONG Jianwei, XIA Xinghui, WANG Minghu, et al. Effect of recurrent sediment resuspension-deposition events on bioavailability of polycyclic aromatic hydrocarbons in aquatic environments [J]. Journal of Hydrology, 2016, 540: 934-946.
105 LI Wang, LI Zhenliang, ZU Bo. Adsorption experiment and model study on phosphorus in sediment in the Three Gorges Reservoir area [J]. Science, Technology and Engineering, 2018, 18(33): 91-97.
105 李旺, 李振亮, 祖波. 三峡库区泥沙对磷的吸附试验及模型研究[J]. 科学技术与工程, 2018, 18(33): 91-97.
106 LUO Liancong, QIN Boqiang, ZHU Guangwei, et al. Sediment distribution and the maximum resuspension depth with disturbance in Lake Taihu [J]. Sediment Research, 2004(1): 9-14.
106 罗潋葱,秦伯强,朱广伟,等.太湖沉积物的分布和动力扰动下最大侵蚀深度的确定[J].泥沙研究,2004(1):9-14.
107 HU Chunhua, HU Weiping, ZHANG Fabing, et al. Sediment resuspension observation in Taihu Lake [J]. Chinese Science Bulletin, 2005(22): 2 541-2 545.
107 胡春华,胡维平,张发兵,等.太湖沉积物再悬浮观测[J].科学通报,2005(22):2 541-2 545.
108 HU Kaiming, WANG Shui, PANG Yong, Suspension-sedimentation of sediment and release amount of internal load in Lake Taihu[J]. Lake Sciences,2014,26(2):191-199.
108 胡开明,王水,逄勇.太湖不同湖区底泥悬浮沉降规律研究及内源释放量估算[J]. 湖泊科学,2014,26(2):191-199.
109 LI Yiping, WANG Jianwei, JIANG Long, et al. The driving force of sediment suspension on sediment-water interface in shallow lakes[J]. Lake Sciences,2017,29(1): 43-51.
109 李一平,王建威,姜龙,等.浅水湖泊动力作用下水—土界面底泥起悬驱动力野外观测[J].湖泊科学, 2017,29(1):43-51.
110 ZHENG Shasha. Simulation of sediment resuspension process and heavy metal migration in Taihu Lake under wind disturbance [D]. Nanjing:Hohai University, 2015.
110 郑莎莎. 风扰动的太湖沉积物再悬浮过程及重金属的迁移模拟[D]. 南京:河海大学, 2015.
111 ZHANG Yanwei, WANG Lei, SUN Hongwen, et al. Impacts of loach bioturbation on the selective bioaccumulation of HBCDD diastereoisomers and enantiomers by mirror carp in a microcosm [J]. Chemosphere, 2016, 163: 471-479.
112 LIU Jingsi, ZHU Xiaosheng, HU Zilong, et al. Effects of different water stratification on vertical distribution of nitrogen in sediment interstitial water: A case study of Three Gorges Reservoir and Xiaowan Reservoir [J]. Chinese Journal of Environmental Science, 2019, 41(8):3 601-3 611.
112 刘静思, 朱晓声, 胡子龙,等. 不同水体分层对沉积物间隙水氮素垂向分布影响:以三峡水库和小湾水库为例[J]. 环境科学, 2019, 41(8): 3 601-3 611.
113 GENG Nan. Multi-media migration and transformation of heavy metal cadmium and enrichment effect of Corbicula fluminea in dynamic water[D]. Nanjing:Hohai University, 2015.
113 耿楠. 动水条件下重金属镉的多介质迁移转化及河蚬的富集效应 [D]. 南京:河海大学, 2015.
114 HOU Lijun, ZHENG Yanling, LIU Min, et al. Anaerobic ammonium oxidation and its contribution to nitrogen removal in China's coastal wetlands[J]. Scientific Reports, 2015, 5: 15 621.
115 DENG Fengyu, HOU Lijun, LIU Min, et al. Dissimilatory nitrate reduction processes and associated contribution to nitrogen removal in sediments of the Yangtze Estuary[J]. Journal of Geophysical Research: Biogeosciences, 2015, 120: 1 521-1 531.
116 CAO Wenzhi, YANG Jingxin, LI Ying, et al. Dissimilatory nitrate reduction to ammonium conserves nitrogen in anthropogenically affected subtropical mangrove sediments in Southeast China[J]. Marine Pollution Bulletin, 2016, 110(1): 155-161.
117 HAN Chao, REN Jinghua,TANG Hao, et al. Quantitative imaging of radial oxygen loss from Vallisneria spirals roots with a fluorescent planar optode[J]. Science of the Total Environment, 2016,569/570: 1 232-1 240.
118 REN Mingyi, DING Shiming, SHI Dan, et al. A new DGT technique comprised in a hybrid sensor for the simultaneous measurement of ammonium, nitrate, phosphorus and dissolved oxygen[J]. Science of the Total Environment,2020,725: 138447.
119 DONG Jianwei, XIA Xinghui, WANG Minghu, et al. Effect of water-sediment regulation of the Xiaolangdi Reservoir on the concentrations, bioavailability, and fluxes of PAHs in the middle and lower reaches of the Yellow River[J]. Journal of Hydrology, 2015, 527: 101-112.
120 YU Shen, LI Hongbo. Perspective on the release of heavy metals via sediment resuspension[J].Ecological Environment,2010,19(7): 1 724-1 731.
120 俞慎, 历红波. 沉积物再悬浮—重金属释放机制研究进展[J]. 生态环境学报, 2010,19(7): 1 724-1 731.
121 PENG Jianfeng, WANG Baozhen, SONG Yonghui, et al. Adsorption and release of phosphorus in the surface sediment of a wastewater stabilization pond[J]. Ecological Engineering, 2007, 31(2): 92-97.
122 XIA Xinghui, YANG Zhifeng, ZHANG Xueqing. Effect of suspended-sediment concentration on Nitrification in river water: Importance of suspended sediment-water interface[J]. Environmental Science & Technology, 2009, 43(10): 3 681-3 687.
123 XIA Xinghui, LIU Ting, YANG Zhifeng, et al. Dissolved organic Nitrogen transformation in River Water: Effects of suspended sediment and organic Nitrogen concentration[J]. Journal of Hydrology, 2013, 484: 96-104.
124 LIU Ting, XIA Xinghui, LIU Shaoda, et al. Acceleration of denitrification in turbid rivers due to denitrification occurring on suspended sediment in oxic waters[J]. Environmental Science & Technology, 2013, 47(9): 4 053-4 061.
125 XIA Xinghui, LI Zhihuang, ZHANG Sibo,et al. Occurrence of anammox on Suspended Sediment (SPS) in oxic river water: Effect of the SPS particle size[J]. Chemosphere, 2019, 235: 40-48.
126 XIA Xinghui, JIA Zhimei, LIU Ting, et al. Coupled nitrification-denitrification caused by Suspended Sediment (SPS) in rivers: Importance of SPS size and composition[J]. Environmental Science & Technology, 2017, 51(1): 212-221.
127 XIA Xinghui, LIU Ting, YANG Zhifeng, et al. Enhanced nitrogen loss from rivers through coupled nitrification-denitrification caused by suspended sediment[J]. Science of the Total Environment, 2017, 579: 47-59.
128 ZHOU Yiyong, LI Jianqiu, ZHANG Min. Vertical variations in kinetics of alkaline phosphatase and P species in sediments of a shallow chinese eutrophic lake(Lake Donghu)[J]. Hydrobiologia, 2001,450: 91-98.
129 QIN Boqiang, Deng Jianmin, PAERL H W, et al. Why Lake Taihu continues to be plagued with cyanobacterial blooms through 10?years (2007-2017) efforts[J]. Chinese Science Bulletin, 2019, 64(6): 354-356.
130 ZHOU Yiyong, SONG Chunlei, CAO Xiuyun, et al. Phosphorus fractions and alkaline phosphatase activity in sediments of a large eutrophic chinese lake (Lake Taihu)[J]. Hydrobiologia, 2008,599:119-116.
131 SONG Chunlei, CAO Xiuyun, ZHOU Yiyong. Fluctuation of size- fractionated alkaline phosphatase after bloom disappearance in two shallow ponds[J]. Fresenius Environmental Bulletin, 2009,18: 982-988.
132 WANG Siyang, XIAO Jian, WAN Lingling, et al. Mutual dependence of Nitrogen and Phosphorus as key nutrient elements: One facilitates dolichospermum flos-aquae to overcome the limitations of the other[J]. Environmental Science & Technology, 2018, 52: 5 653-5 661.
133 WU Qinglong, WU Yucheng, XING Peng, et al. Chapter 4: Nitrogen oxidation and its microbiological processes at sediment interface[M]// FAN Chengxin,ZHOU Yiyong,WU Qinglong,et al. The sedimen-water interface of lakes: Processes and effects. Beijing: Science Press, 2013:82-116.[
吴庆龙,吴宇澄,邢鹏,等.第4章 沉积物界面氮氧化及其微生物学过程[M]//范成新,周易勇,吴庆龙,等.
湖泊沉积物水界面过程与效应.北京:科学出版社,2013:82-116.]
134 WU Yonghong, LIU Jiantong, YANG Linzhang, et al. Allelopathic control of cyanobacterial blooms by periphyton biofilms[J]. Environmental Microbiology, 2011,13:604-615.
135 LIU Yuansi, GONG Lixue, MU Xiaoying, et al. Characterization and co-occurrence of microbial community in epiphytic biofilms and surface sediments of wetlands with submersed macrophytes[J]. Science of the Total Environment, 2020,715: 136950.
136 ZHANG Lei, GU Xiaozhi, FAN Chengxin. Impact of different benthic animals on phosphorus dynamics across the sediment-water interface[J]. Journal of Environmental Sciences,2010,22(11):1 674-1 682.
137 SHANG Jingge, ZHANG Lu, ZHANG Bo, et al. Disturbation effect of Tanypus chinensis larvae on denitrification rate and process in sedimen[J]. Journal of Lake Science, 2010,22(5): 708-713.
137 商景阁,张路,张波,等.中国长足摇蚊(Tanypus chinensis)幼虫底栖扰动对沉积物溶解氧特征及反硝化的影响[J].湖泊科学, 2010,22(5):708-713.
138 SMITH V. Low nitrogen to phosphorus ratios favor dominance by blue-green algae in lake phytoplankton[J]. Science,1983, 221: 669-671.
139 SCHEFFER M, RINALDI S, GRAGNANI A, et al. On the dominance of filamentous cyanobacteria in shallow, turbid lakes[J]. Ecology, 1997, 78: 272-282.
140 XIE Liqiang, XIE Ping, LI Sixin, et al. The low TN∶TP ratio, a cause or a result of microcystis blooms?[J]. Water Research,2003, 37: 2 073-2 080.
141 XU Hai, PAERL H W, QIN Boqiang, et al. Nitrogen and phosphorus inputs control phytoplankton growth in eutrophic Lake Taihu[J]. Limnology and Oceanography, 2010, 55: 420-432.
142 TONG Yindong, ZHANG Wei, WANG Xuejun, et al. Decline in chinese lake phosphorus concentration accompanied by shift in sources since 2006[J]. Nature Geoscience, 2017, 10: 507.
143 S?NDERGAARD M. Role of sediment and internal loading of phosphorus in shallow lakes[J]. Hydrobiologia, 2003. DOI:10.1023/B:HYDR.0000008611.12704.dd.
doi: 10.1023/B:HYDR.0000008611.12704.dd
144 YANG Liuyan, YANG Xinyan, REN Liman, et al. Mechanism and control strategy of cyanobacterial bloom in Lake Taihu [J]. Journal of Lake Sciences, 2019,31(1): 18-27.
144 杨柳燕,杨欣妍,任丽曼,等. 太湖蓝藻水华暴发机制与控制对策[J].湖泊科学, 2019,31(1):18-27.
145 WEI Hailun, CAI Jingong, WANG Guoli, et al. The diversity of organic matter in marine sediments and the suspiciousness of source parameters: A review[J]. Advances in Earth Science, 2018, 33(10): 1 014-1 033.
145 韦海伦,蔡进功,王国力,等. 海洋沉积物有机质赋存的多样性与物源指标的多疑性综述[J]. 地球科学进展,2018,33(10):1 014-1 033.
146 XIE Liqiang, XIE Ping, TANG Huijuan. Enhancement of dissolved phosphorus release from sediment to lake water by Microcystis blooms—An enclosure experiment in a hyper-eutrophic, subtropical chinese lake[J]. Environmental Pollution, 2003, 122: 391-399.
147 SUN Rui, SUN Pengfei, ZHANG Jianhong, et al. Microorganisms-based methods for harmful algal blooms control: A review[J]. Bioresource Technology, 2018, 248: 12-20.
148 ZHU Lin, SHI Wenqing, van Dam B, et al. Algal accumulation decreases sediment nitrogen removal by uncoupling Nitrification-denitrification in shallow Eutrophic lakes[J]. Environmental Science & Technology, 2020, 54(10):6 194-6 201.
149 HAN Chao, DING Shiming, YAO Lei, et al. Dynamics of phosphorus-iron-sulfur at the sediment-water interface influenced by algae blooms decomposition[J]. Journal of Hazardous Materials, 2015, 300: 329-337.
150 WU Songjun, ZHAO Yanping, CHEN Yuanyuan, et al. Sulfur cycling in freshwater sediments: A cryptic driving force of iron deposition and phosphorus mobilization[J]. Science of the Total Environment, 2019, 657: 1 294-1 303.
151 ZHAO Yanping, ZHANG Zhongqian, WANG Guoxiang, et al. High sulfide production induced by algae decomposition and its potential stimulation to phosphorus mobility in sediment[J]. Science of the Total Environment, 2019, 650: 163-172.
152 BAI Xiuling, DING Shiming, FAN Chengxin, et al. Organic phosphorus species in surface sediments of a large, shallow, eutrophic lake, Lake Taihu, China[J]. Environmental Pollution, 2009, 157: 2 507-2 513.
153 Ni Zhaokui, WANG Shengrui, CAI Jingjing, et al. The potential role of sediment organic phosphorus in algal growth in a low nutrient lake[J]. Environal Pollution, 2019, 255(Pt 2): 113235.
154 NI Zhaokui, WANG Shengrui, WANG Yuemin. Characteristics of bioavailable organic phosphorus in sediment and its contribution to lake eutrophication in China[J]. Environal Pollution, 2016, 219: 537-544.
155 YAO Xiaohong, ZHANG Yunlin, ZHANG Lu, et al. Emerging role of dissolved organic nitrogen in supporting algal bloom persistence in Lake Taihu, China: Emphasis on internal transformations[J]. Science of the Total Environment, 2020, 736: 139497.
156 LI Hui, SONG Chunlei, CAO Xiuyun, et al. The phosphorus release pathways and their mechanisms driven by organic carbon and nitrogen in sediments of eutrophic shallow lakes[J]. Science of the Total Environment, 2016, 572: 280.
157 SHEN Qiushi, FAN Chengxin. Identification of black suspended particles in the algae-induced black bloom using multi-approaches[J]. Lake Sciences,2015, 27(3):591-598.
157 申秋实,范成新.太湖湖泛水体显黑颗粒的元素形态分析与鉴定[J].2015, 27(3):591-598.
158 LU Xin. Forming mechanisms of major odorous compounds (VSCs) in algae-induced black water bloom and preventive effects of sediment dredging on their production[D]. Beijing: Chinese Academy of Sciences, 2012: 70-77.
158 卢信.藻源性湖泛主要致臭物(VSCs)形成机制及底泥疏浚影响研究[D].北京:中国科学院研究生院,2012:70-77.
159 CAI Ping, WU Yuchen, LIU Xin, et al. The contribution of sediment and algal to the formation of black bloom and their potential to supply the black substance in waters in Lake Taihu[J]. Lake Sciences, 2015,27(3):575-582.
159 蔡萍,吴雨琛,刘新,等.底泥和藻体对太湖湖泛的诱发及水体致黑物的供应潜力[J].湖泊科学,2015,27(3):575-582.
160 FENG Z, FAN C, HUANG W, et al. Microorganisms and typical organic matter responsible for lacustrine "black bloom"[J]. Science of the Total Environment, 2014,470/471: 1-8.
161 WAN Guojiang, HU Qile, CAO Long, et al. Resource exploitation environmental disaster geochemistry: An example from Fe and Mn pollution in Lake Aha, Guizhou Province[J]. Frontier of Geosciences, 2001, 8(2): 353-358.
161 万国江,胡其乐,曹龙,等. 资源开发—环境灾害—地球化学——以贵州阿哈湖铁、锰污染为例[J]. 地学前缘,2001,8(2):353-358.
162 DAI Guohua, LIU Xinhui. Factors affacting the migration of persistent organic pollutants across the sediment-water interface of aquatic environment.[J] Environmental Chemistry, 2011, 30(1): 224-230.
162 戴国华,刘新会. 影响沉积物—水界面持久性有机污染物迁移行为的因素研究[J]. 环境化学, 2011, 30(1): 224-230.
163 ZHOU Wenxiu, CHEN Weifang, LI Peng, et al. Occurrence and distribution of Polyhalogenated Carbazoles (PHCs) in sediments from the northern South China Sea[J]. Science of the Total Environment, 2020,753:142 072-142 072.
164 MA Deyi, WANG Juying, HONG Ming, et al. Methodology analysis of marine environmental quality benchmark research [M]. Beijing: Ocean Press,2011.
164 马德毅,王菊英,洪鸣,等. 海洋环境质量基准研究方法学浅析[M]. 北京:海洋出版社,2011.
165 WANG Shengrui, WU Zhihao, LUO Jun. Transfer mechanism, uptake kinetic process, and bioavailability of P, Cu, Cd, Pb, and Zn in macrophyte rhizosphere using diffusive gradients in thin films[J]. Environmental Science & Technology, 2018, 52: 1 096-1 108.
166 FAN Chengxin, ZHU Yuxin, JI Zhijun, et al. Characteristics of the pollution of heavy metals in the sediments of Yilihe River, Taihu Basin [J]. Journal of Lake Sciences, 2002,14(3): 235-241.
166 范成新,朱育新,吉志军,等.太湖宜溧河水系沉积物的重金属污染特征[J]. 湖泊科学,2002,14(3):235-241.
167 MA Deyi, WANG Juying. Evaluation on potential ecological risk of sediment pollution in main estuaries of China[J]. China Environmental Science, 2003, 23(5): 521-525.
167 马德毅,王菊英.中国主要河口沉积物污染及潜在生态风险评价[J]. 中国环境科学,2003, 23(5):521-525.
168 ZENG Yan, ZHANG Wei, CHEN Jingan, et al. Analysis of heavy metal pollution in the sediment of the inflow-lake rivers of the Hongfeng Lake [J]. Earth and Environment, 2010, 38(4): 470-475.
168 曾艳, 张维, 陈敬安, 等. 红枫湖入库河流沉积物中重金属污染状况分析[J]. 地球与环境, 2010, 38(4): 470-475.
169 ZHAO Yanmin, QIN Yanwen, CAO Wei, et al. Speciation and ecological risk of heavy metals in surface sediments of Dongting Lake[J]. Chinese Journal of Environmental Science Research, 2020, 33(3): 572-580.
169 赵艳民, 秦延文, 曹伟,等. 洞庭湖表层沉积物重金属赋存形态及生态风险评价[J]. 环境科学研究, 2020, 33(3): 572-580.
170 FENG Xinbin, JIANG Hongmei, QIU Guangle, et al. Mercury massbalance study in Wujiangdu and Dongfeng Reservoirs, Guizhou, China[J]. Environmental Pollution,2009,157(10): 2 594-2 603.
171 CHEN Jingan, WANG Jingfu, GUO Jianyang, et al. Eco-environment of reservoirs in China: Characteristics and research prospects[J]. Progress in Physical Geography, 2018,42(2):185-201.
172 WANG Xinxin, SU Ping,LIN Qidong, et al. Distribution, assessment and coupling relationship of heavy metals and macroinvertebrates in sediments of the Weihe River Basin[J]. Sustainable Cities and Society, 2019,50:101665.
173 REN Mingyi, WANG Yan, DING Shiming, et al. Development of a new diffusive Gradients in Thin Films (DGT) method for the simultaneous measurement of CH3Hg+ and Hg2+[J]. New Journal of Chemistry, 2018,42(10):7 976-7 983.
174 DING Zhiyong, PU Jia, GILILI Abdulwaili. Heavy metal contamination characteristics and its assessment in surface sediments of major lakes in China [J]. Environmental Engineering, 2017, 35(6): 126-141.
174 丁之勇, 蒲佳, 吉力力·阿不都外力. 中国主要湖泊表层沉积物总金属污染特征与评价分析[J]. 环境工程, 2017, 35(6): 126-141.
175 YANG Jinxi, ZHANG Yanfeng, ZHU Lingyan. Pollution and risk assessment of typical heavy metals in river sediments of seven major watersheds in China [J]. Environnental Sciencephalitis Research, 2017, 30(3): 423-432.
175 阳金希, 张彦峰, 祝凌燕. 中国七大水系沉积物中典型重金属生态风险评估[J]. 环境科学研究, 2017, 30(3): 423-432.
176 CHEN Ruihui, CHEN Haiyang, SONG Liuting, et al. Characterization and source apportionment of heavy metals in the sediments of Lake Tai (China) and its surrounding soils[J]. Science of the Total Environment, 2019, 694: 133819.
177 YI Xiaoyi, LI Huizhen, MA Ping, et al. Identifying the causes of sediment-associated toxicity in urban waterways in South China: Incorporating bioavailability-based measurements into whole-sediment toxicity identification evaluation[J]. Environmental Toxicology and Chemistry, 2015, 34(8): 1 744-1 750.
178 LI Chaocan, HUO Shouliang, YU Zhiqiang, et al. National investigation of semi-volatile organic compounds (PAHs, OCPs, and PCBs) in lake sediments of China: Occurrence, spatial variation and risk assessment[J]. Science of the Total Environment, 2017,579:325-336.
179 ZHANG Yu. Distribution and risk assessment of new organic pollutants in sediments from the intertidal zone of the New River Estuary[D]. Qingdao:Qingdao University, 2019:1-40.
179 张宇.新河入海口潮间带沉积物中新型有机污染物的分布及风险评估[D].青岛:青岛大学,2019:1-40.
180 CHEN Manying, LUO Xiaojun, ZHANG Xiulan, et al. Chlorinated paraffins in sediments from the Pearl River Delta, South China: Spatial and temporal distributions and implication for processes[J]. Environmental Science & Technology, 2011, 45: 9 936-9 943.
181 LI Huizhen, YI Xiaoyi, CHENG Fei, et al. Identifying organic toxicants in sediment using effect-directed analysis: A combination of bioaccessibility—Based extraction and high-throughput midge toxicity testing[J]. Environmental Science & Technology, 2019, 53: 996-1 003.
182 LI Huizhen, SUN Baoquan, CHEN Xin, et al. Addition of contaminant bioavailability and species susceptibility to a sediment toxicity assessment: Application in an urban stream in China[J]. Environmental Pollution,2013,178: 135-141.
183 BAO Lianjun, ZENG E Y. Application of passive sampling techniques in measurement of HOCs in aquatic environments[M]//Zeng E Y. Persistent Organic Pollutants (POPs): Analytical techniques, environmental fate and biological effects[M]. Amsterdam: Elsevier, 2015: 135-159.
184 LIAO Chunyang, BAO Lianjun, CUI Xinyi, et al. Research methods and applications of bioavailability of organic pollutants [M]// JIANG Guibin,ZHENG Minghui,SUN Hongwen,et al. Frontier of Environmental Chemistry (Vol. 2).Bejing:Science Press, 2019:47-67.[
廖春阳,鲍恋君,崔欣毅,等.有机污染物生物有效性研究的方法与应用[M]// 江桂斌,郑明辉,孙红文,等.
环境化学前沿(第二辑). 北京:学出版社,2019:47-67.]
185 ZHANG Shuguang, ZHAO Peilun, LI Yaqing. Study on water quality evaluation standard of muddy rivers [J]. People's Yellow River, 1996,7:29-33.
185 张曙光,赵沛伦,李雅卿. 多泥沙河流水质评价标准研究[J]. 人民黄河,1996, 7:29-33.
186 WANG Lixin, CHEN Jingsheng, LIU Huamin. Research on deriving sediment quality criteria for heavy metals using the biological effect database approachs as Jinzhou Gulf, Bohai Sea an example[J]. Journal of Inner Mongolia University (Natural Science Edition ), 2004(4): 467-472.
186 王立新,陈静生,刘华民. 应用生物效应数据库法建立沉积物重金属质量基准的初步研究——以渤海锦州湾海洋沉积物为例[J].内蒙古大学学报:自然科学版,2004(4):467-472.
187 ZHU Lingyan, DENG Baole, LIU Nannan, et al. Application of equilibrium partitioning approach to derive sediment quality criteria for heavy metals[J]. Environmental Science Research, 2009,22(7):762-767.
187 祝凌燕,邓保乐,刘楠楠,等. 应用相平衡分配法建立污染物的沉积物质量基准[J].环境科学研究,2009,22(7):762-767.
188 ZHANG Ting, ZHONG Wenjue, ZENG Yi, et al. Sediment heavy metals quality criteria for fresh waters based on biological effect database approach [J]. Acta Ecologica Sinica Sinica, 2012, 23(9): 2 587-2 594.
188 张婷,钟文珏,曾毅,等. 应用生物效应数据库法建立淡水水体沉积物重金属质量基准[J]. 应用生态学报,2012,23(9):2 587-2 594.
189 WANG Juying. Environmental quality assessment of marine sediments[D]. Qingdao: Ocean University of China,2004.
189 王菊英. 海洋沉积物的环境质量评价研究[D].青岛:中国海洋大学,2004.
190 General Administration of Quality Supervision, Inspection and Quarantine of the People's Republic of China. Marine Sediment Quality[S]. 2002-03-10. Beijing: China Standards Press,2002. [中华人民共和国国家质量监督检验检疫总局. 海洋沉积物质量[S]. 2002-03-10. 北京:中国标准出版社,2002.]
191 FAN Chengxin, ZHANG Lu. Taihu Lake: Principles of sediment pollution and remediation[M]. Beijing: Science Press,2009.
191 范成新,张路.太湖——沉积物污染与修复原理[M].北京:科学出版社,2009.
192 ZHAO Bin, HU Xiaozhen, WU Xianhua. Pilot study on the inhibition of phosphorus release from Dianchi Lake sediment by calcite overburden[J]. Journal of Yuxi Normal University, 2010,26(8): 29-32.
192 赵斌,胡小贞,吴献花.方解石覆盖层抑制滇池底泥磷释放的中试试验研究[J].玉溪师范学院学报,2010,26(8):29-32.
193 CHEN Chunmei. Studying on control of organic phosphorus release in sediment using in situ capping[D]. Chengdu: ChengduUniversity of Technology,2018.
193 陈春梅.原位覆盖技术控制底泥中有机磷释放的研究[D].成都:成都理工大学,2018.
194 SHANG Jingge, HE Wei, SHAO Shiguang, et al. Thin layer capping to eliminate alage-caused black bloom in Eutrophic Lakes[J]. Journal of Lake Sciences,2015,27(4):599-606.
194 商景阁,何伟,邵世光,等.底泥覆盖对浅水湖泊藻源性湖泛的控制模拟[J]. 湖泊科学, 2015,27(4):599-606.
195 LIN Jianwei, HE Siqi, ZHAN Yanhui, et al. Assessment of sediment capping with zirconium-modified bentonite to intercept phosphorus release from sediments[J].Environmental Science and Pollution Research,2019,26(4):3 501-3 516.
196 KONG Ming, LIU Feifei, TAO Yue, et al. First attempt for in situ capping with Lanthanum Modified Bentonite (LMB) on the immobilization and transformation of organic phosphorus at the sediment-water interface[J]. Science of the Total Environment, 2020,741(1):140342.
197 YU Yanghua, CHEN Cheng, WU Yonggui, et al. Study on sediment coverage effect of deep valley lake under anaerobic condition[J]. Environmental Engineering, 2015,33(2): 53-57.
197 喻阳华,陈程,吴永贵,等.厌氧条件下深谷型湖泊底泥覆盖效果研究[J].环境工程, 2015,33(2):53-57.
198 ZOU Yinhong, ZHANG Runyu, CHEN Jing'an, et al. Research advance in the application of clay minerals to phosphorus pollution control in eutrophic water bodies and sediments[J]. Advances in Earth Science,2018,33(6):578-589.
198 邹银洪,张润宇,陈敬安,等.黏土矿物在富营养化水体和底泥磷污染控制中的应用研究进展[J].地球科学进展,2018,33(6):578-589.
199 LIU Qunqun, SHENG Yanqing, WANG Wenjing, et al. Remediation and its biological responses of Cd contaminated sediments using biochar and minerals with nanoscale zero-valent iron loading[J]. Science of the Total Environment, 2020, 713: 13650.
200 MA Tao, SHENG Yanqing, MENG Yingjie, et al. Multistage remediation of heavy metal contaminated river sediments in a mining region based on particle size[J]. Chemosphere, 2019,225: 83-92.
201 ZHAO Guoqiang, SHENG Yanqing, LI Changyu, et al. Restraint of enzymolysis and photolysis of organic phosphorus and pyrophosphate using synthetic zeolite with humic acid and lanthanum[J]. Chemical Engineering Journal, 2020,386: 123791.
202 YIN Hongbin, ZHU Jincan. In situ remediation of metal contaminated lake sediment using naturally occurring, calcium-rich clay mineral-based low-cost amendment[J]. Chemical Engineering Journal, 2016, 285:112-120.
203 YIN Hongbin, KONG Ming, HAN Meixiang, et al. Influence of sediment resuspension on the efficacy of geoengineering materials in the control of internal phosphorous loading from shallow eutrophic lakes[J]. Environment Pollution, 2016, 219: 568-579.
204 HUNG Changmao, HUANG Chinpao, Sushiuang LAM, et al. The removal of Polycyclic Aromatic Hydrocarbons (PAHs) from marine sediments using persulfate over a nano-sized iron composite of magnetite and carbon black activator[J]. Journal of Environmental Chemical Engineering, 2020, 8: 104440.
205 BAO Xianming, CHEN Kaining, FAN Chengxin. Effects on nitrogen and phosphorus distribution in interstitial water and sediment-water nitrogen and phosphorus release with growing of submerged macrophytes[J]. Lake Sciences, 2006(5):515-522.
205 包先明,陈开宁,范成新.沉水植物生长对沉积物间隙水中的氮磷分布及界面释放的影响[J].湖泊科学, 2006(5):515-522.
206 CHEN Kaining,CHEN Xiaofeng, CHEN Weimin, et al. Effects of sediments on submerged macrophytes growth[J].Chinese Journal of Applied Ecology, 2006,17(8): 1 511-1 516.
206 陈开宁,陈小峰,陈伟民,等.不同基质对四种沉水植物生长的影响[J].应用生态学报,2006,17(8): 1 511-1 516.
207 ZHAO Guoqiang, SHENG Yanqing, WANG Chuanyuan, et al. In situ microbial remediation of crude oil-soaked marine sediments using zeolite carrier with a polymer coating[J]. Marine Pollution Bulletin, 2018, 129(1): 172-178.
208 WANG Chuanyuan,HE Shijie,ZOU Yanmei, et al. Quantitative evaluation of in-situ bioremediation of compound pollution of oil and heavy metal in sediments from the Bohai Sea, China[J]. Marine Pollution Bulletin, 2020, 150: 110787.
209 LIU Huiqing. Environmental dredging in the internal source treatment of lake pollution [J]. Water Transport Engineering, 2000(11): 21-27.
209 柳惠青.湖泊污染内源治理中的环保疏浚[J].水运工程,2000(11):21-27.
210 NIAN Yuegang, FAN Chengxin, KONG Fanxiang, et al. Research and engineering demonstration of environmental dredging series technology[J]. China Water Conservancy, 2006(17): 40-42, 58.
210 年跃刚,范成新,孔繁翔,等.环保疏浚系列化技术研究与工程示范[J].中国水利,2006(17):40-42,58.
211 FAN Chengxin, ZHONG Jicheng, ZHANG Lu, et al. Research progress and prospect of environmental dredging decision of lake sediment[J]. Journal of Lake Sciences,2020,32(5): 1 254-1 277.
211 范成新,钟继承,张路,等. 湖泊底泥环保疏浚决策研究进展与展望[J]. 湖泊科学,2020, 32(5):1 254-1 277.
212 JIN Xiangcan, LI Jinjun, ZHANG Qingbo. Technical guide for environmental dredging of lakes and rivers [M]. Beijing: Science Press, 2013: 30-31, 38-41, 68, 169-176.
212 金相灿,李进军,张晴波. 湖泊河流环保疏浚工程技术指南[M]. 北京:科学出版社,2013: 30-31,38-41,68,169-176.
213 ZHU Wei, MIN Fanlu, Yiyan Lü, et al. Subject of "mud science and application technology" and its research progress[J]. Geotechnical Mechanics, 2013, 34(11): 3 041-3 054.
213 朱伟, 闵凡路, 吕一彦, 等. “泥科学与应用技术”的提出及研究进展[J]. 岩土力学, 2013, 34(11): 3 041-3 054.
214 ZHANG Chunlei, ZHU Wei, DAMU Yizhang. Application of solidification technology of polluted sediment in engineering [C]// Chinese society of Environmental Sciences. 2008 annual meeting of Chinese society of environmental sciences. Proceedings of excellent papers (Vol.I). 2008: 695-698.[
214 张春雷,朱伟,大木宜章. 湖泊污染底泥的固化资源化技术在工程中的应用[C]// 中国环境科学学会. 2008中国环境科学学会学术年会优秀论文集(上卷). 2008:695-698.]
215 FAN Chengxin, CHEN Shuang. Determination method of ecological dredging area of polluted sediment [P]. ZL201010287880.7, 2012-01-25.
215 范成新,陈爽. 水体污染底泥生态疏浚面积的确定方法[P]. ZL201010287880.7,2012-01-25.
216 JIANG Xia, ZHANG Qingbo, WANG Shuhang. Study on environmental dredging planning of toxic and harmful sediment and high nitrogen and phosphorus pollution in Taihu Lake [M]. Beijing:Science Press,2014.
216 姜霞,张晴波,王书航. 太湖有毒有害与高氮磷污染底泥环保疏浚规划研究[M].北京:科学出版社,2014.
217 WANG Qiujuan. Determination of nitrogen pollution and sediment dredging amount in three northern Taihu Lake areas [D]. Haerbin: Northeast Forestry University, 2012.
217 王秋娟.太湖北部三个湖区氮污染状况及其底泥疏浚量的确定[D].哈尔滨:东北林业大学,2012.
218 DING Tao, TIAN Yingjie, LIU Jinbao, et al. Calculation of the environmental dredging depth for removal of river sedimnets contaminated by heavy metals[J]. Environmental Earth Sciences, 2015, 74(5):4 295-4 302.
219 GUO Zhiyong, YANG Jianhua, CHEN Jiuxiao. Design of new environmental protection cutter for cutter suction dredger [J]. China Harbor Construction, 2014(12): 66-68.
219 郭志勇,杨建华,陈九肖. 绞吸挖泥船新型环保绞刀设计[J].中国港湾建设,2014(12):66-68.
220 LI Jingui, LI Jinjun, YANG Jianhua. Precise dredging technology for polluted sediment[J]. China Harbour Construction, 2004(6): 11-14, 20.
220 李金贵,李进军,杨建华. 污染底泥精确疏浚技术[J].中国港湾建设,2004(6):11-14,20.
221 PU Peimin, WANG Guoxiang, HU Chunhua, et al. Can we control lake eutrophication by dredging?[J]. Lake Sciences, 2000, 12(3): 269-279.
221 濮培民,王国祥,胡春华,等. 底泥疏浚能控制湖泊富营养化吗?[J] 湖泊科学, 2000, 12(3): 269-279.
222 FAN Chengxin, ZHANG Lu, WANG Jianjun, et al. Processes and mechanism of effects of sludge dredging on internal source release in lakes[J]. Chinese Science Bulletin, 2004,49(17):1 853-1 859.
222 范成新,张路,王建军,等.湖泊底泥疏浚对内源释放影响的过程与机理研究[J].科学通报,2004,49(15):1 523-1 528.
223 LIU Cheng, DU Yiheng, YIN Hongbin, et al. Exchanges of nitrogen and phosphorus across the sediment-water interface influenced by the external suspended particulate matter and the residual matter after dredging[J]. Environmental Pollution, 2019,246: 207-216.
224 ZHONG Jicheng,FAN Chengxin, ZHANG Lu, et al. Significance of dredging on sediment denitrification in Meiliang Bay, China: A year long simulation study[J]. Journal of Environmental Sciences, 2010,22(1): 68-75.
225 LIU Cheng, ZHONG Jicheng, WANG Jianjun, et al. Fifteen-year study of environmental dredging effect on variation of nitrogen and phosphorus exchange across the sediment-water interface of an urban lake[J]. Environmental Pollution, 2016, 219: 639-648.
226 ZHU Wei. Excerpt from the comprehensive discussion of the Special Committee on dredging and mud treatment/utilization of Chinese Water Conservancy Society [J]. Water Resources Protection, 2018, 34(4): 93-94.
226 朱伟. 中国水利学会疏浚与泥处理利用专委会综合讨论摘登[J]. 水资源保护, 2018, 34(4): 93-94.
227 ZHANG Xuanqi, JIANG Bo. Experimental study on consolidation treatment of lake sediment in Dongqian Lake Dredging and reclamation Section [J]. People's Pearl River, 2007(4): 66-68.
227 张选岐, 江波. 东钱湖疏浚吹填试验段湖泊底泥固结处理试验研究[J]. 人民珠江, 2007(4): 66-68.
228 HUANG Yinghao, DONG Chan. Review on principle and classification of sludge treatment technology [J]. People's Yellow River, 2014, 36 (7): 91-94.
228 黄英豪, 董婵. 淤泥处理技术原理及分类综述[J]. 人民黄河, 2014, 36(7): 91-94.
229 WU Silin, ZHU Wei, LIU Jiming, et al. Change laws of mud property and problems in typical environmental dredging treatment projects[J]. Geotechnical Engineering, 2019, 41(12): 2 290-2 296.
229 吴思麟, 朱伟, 刘既明, 等. 环保疏浚泥处理工程泥性质变化规律及问题分析[J]. 岩土工程学报, 2019, 41(12): 2 290-2 296.
230 WU Silin, ZHU Wei, MIN Fanlu, et al. Clogging mechanism and effect of cake permeability in soil-water separation using vacuum filtration[J]. Geotechnical Engineering, 2017, 39 (8): 1 530-1 537.
230 吴思麟, 朱伟, 闵凡路, 等. 泥浆真空抽滤泥水分离中堵塞机理及规律性研究[J]. 岩土工程学报, 2017, 39(8): 1 530-1 537.
231 BAO Jianping, ZHU Wei, WANG Shuncai, et al. Stabilization effect of heavy metals in solidified sludge[J]. Journal of Hohai University (Natural Science Edition), 2011, 39(1): 24-28.
231 包建平, 朱伟, 汪顺才, 等. 固化对淤泥中重金属的稳定化效果[J]. 河海大学学报:自然科学版, 2011, 39(1): 24-28.
232 FAN Chengxin, WANG Jiaquan, YANG Xiangdong, et al. Background effect and control of phosphorus in Chaohu Lake[M]. Beijing: Environmental Science Press, 2012:190-220.
232 范成新,汪家权,羊向东,等.巢湖磷本底影响及其控制[M].北京:环境科学出版社,2012:190-220.
233 FANG Hongwei, LI Xiaocui, HUANG Lei, et al. Ceramization of contaminated sediment backfill technology and its effects of sediment remediation[J]. Water Resources Protection, 2019, 35 (3): 1-6.
233 方红卫, 李晓翠, 黄磊, 等. 受污染底泥陶粒化回填技术及其底泥修复效果[J]. 水资源保护, 2019, 35(3): 1-6.
234 WU Silin, ZHU Wei, Yiyan Lü, et al. Quality control indexes and curing agent values for submerged poured solidifying-silt island:Case study of the artificial island of Dalian Bay, China[J]. Construction and Building Materials, 2018, 190: 664-671.
235 CHEN Fahu, FU Bojie, XIA Jun, et al. Major advances in studies of the physical geography and living environment of China during the past 70 years and future prospects[J]. Science China Earth Sciences, 2019,62(11): 1 665-1 701.
235 陈发虎,傅伯杰,夏军,等. 近70年来中国自然地理与生存环境基础研究的重要进展与展望[J].中国科学:地球科学,2019,49(11):1 659-1 696.
236 ZHANG Xiaodong, LIU Zhifei, ZHANG Yanwei, et al. Research progress on source-to-sink transport processes of marine microplastics[J]. Advances in Earth Science, 2019,34(9):936-949.
236 张晓栋,刘志飞,张艳伟,等.海洋微塑料源汇搬运过程的研究进展[J].地球科学进展,2019,34(9):936-949.
237 JIANG Helong, WANG Changhui, BAI Leilei, et al. Advances and prospects in lake environment science and engineering: A review[J]. Lake Sciences,2020,32(5):1 278-1 296.
237 江和龙,王昌辉,白雷雷,等.湖泊环境科学与工程技术研究进展探讨[J].湖泊科学, 2020,32(5):1 278-1 296.
238 ZHANG Min, WANG Xiangchun, YANG Long, et al. Research on progress in combined remediation technologies of heavy metal polluted sediment[J]. International Journal of Environmental Research and Public Health, 2019,16(24):5 098.
[1] 董治宝,吕萍,李超,胡光印. 火星风条痕特征及其形成机制[J]. 地球科学进展, 2020, 35(9): 902-911.
[2] 吴佳梅,彭秋志,黄义忠,黄亮. 中国植被覆盖变化研究遥感数据源及研究区域时空热度分析[J]. 地球科学进展, 2020, 35(9): 978-989.
[3] 赵仁杰,鄢全树,张海桃,关义立,葛振敏,袁龙,闫施帅. 全球俯冲沉积物组分及其地质意义[J]. 地球科学进展, 2020, 35(8): 789-803.
[4] 李侠祥, 刘昌新, 王芳, 郝志新. 中国投资对“一带一路”地区经济增长和碳排放强度的影响[J]. 地球科学进展, 2020, 35(6): 618-631.
[5] 朱艳宸,李丽,王鹏,贺娟,贾国东. 海洋氮循环中稳定氮同位素变化与地质记录研究进展[J]. 地球科学进展, 2020, 35(2): 167-179.
[6] 傅焓埔, 刘群, 胡修棉. 水下沉积物重力流与海底扇相模式研究进展[J]. 地球科学进展, 2020, 35(2): 124-136.
[7] 刘柏妤, 张虎才, 常凤琴, 张扬, 张晓楠, 冯仡哲, 李华勇. 茈碧湖现代沉积特征及其环境指示意义[J]. 地球科学进展, 2020, 35(2): 198-208.
[8] 刘凯,聂格格,张森. 中国19512018年气温和降水的时空演变特征研究[J]. 地球科学进展, 2020, 35(11): 1113-1126.
[9] 谢彦君, 任福民, 李国平, 王铭杨, 杨慧. 影响中国双台风活动气候特征研究[J]. 地球科学进展, 2020, 35(1): 101-108.
[10] 郝志新,吴茂炜,张学珍,刘洋,郑景云. 过去千年中国年代和百年尺度冷暖阶段的干湿格局变化研究[J]. 地球科学进展, 2020, 35(1): 18-25.
[11] 蒋诗威,周鑫. 中国东南地区中世纪暖期和小冰期夏季风降水研究进展[J]. 地球科学进展, 2019, 34(7): 697-705.
[12] 高峰,赵雪雁,宋晓谕,王宝,王鹏龙,牛艺博,王伟军,黄春林. 面向SDGs的美丽中国内涵与评价指标体系[J]. 地球科学进展, 2019, 34(3): 295-305.
[13] 张咏华,吴自军. 陆架边缘海沉积物有机碳矿化及其对海洋碳循环的影响[J]. 地球科学进展, 2019, 34(2): 202-209.
[14] 蒋俊霞,杨丽薇,李振朝,高晓清. 风电场对气候环境的影响研究进展[J]. 地球科学进展, 2019, 34(10): 1038-1049.
[15] 张宸嘉, 方一平, 陈秀娟. 基于文献计量的国内可持续生计研究进展分析[J]. 地球科学进展, 2018, 33(9): 969-982.