海洋生态学

海洋生物生产过程 

海洋生物地球化学

铝对海洋微藻固碳、碳循环和气候变化影响

短期盐度降低对海洋微食物网影响

粒径谱表征的食物网结构与功能

    通过长期研究，我们初步揭示铝有益于海洋微藻固碳的作用机制（提高海洋微藻利用溶解有机磷、铁的效率及固氮）及铝对海洋微藻颗粒有机碳分解的影响规律，发现地球历史时期沙尘沉降向南大洋输入铝的量与大气CO₂ 浓度、气温存在显著的负相关关系。 在铁假说的基础上， 提出了关于铝增加海洋碳汇， 影响气候变化的“铁铝假说：阐释铝提高上层海洋碳固定，降低生源碳分解速率，增加碳向深海输出与封存，从而增强海洋吸收 CO₂ 的碳汇能力，调节大气中CO₂浓度，在地球历史时期和现代气候变化过程发挥重要作用。根据铁铝假说，我们提出基于“海洋铝施肥”的增汇负排放方法与技术。

    相关工作改变了“铝在海洋生物地球化学循环中不重要”的传统认知，引发了海洋碳汇新认识，为开发增汇（负排放）技术，实现“碳中和”目标，提供了新路径。

   我们将继续从海洋生物地球化学、生态学、生物化学、分子生物学等多学科角度，研究铝提高海洋微藻固碳和海洋生物碳泵效率的作用机制。

铁铝假说及海洋铝施肥原理示意图。自然铁施肥过程如（但不限于）沙尘气溶胶沉降不仅向海洋输入铁（Fe）还带来铝（Al）。Al一方面提高海洋浮游植物利用溶解有机磷（DOP）、Fe和N₂（固氮）效率，增加上层海洋固碳；另一方面降低生源碳分解速率，提高碳向深海输出、封存，增强海洋碳汇能力，从而影响气候变化，在地球历史时期和现代气候变化过程中发挥重要作用。

生态学是关于生物群体的最高和最复杂层次的学科。他研究整体论和涌现性（emergent property），是一门自上而下研究生命特性的科学。即使是在实验室工作的（关注分子和细胞层次的）倔强科学家们，在他们的内心深处，也深知生物学家最终还是要到达生态学这个层次。为了彻底理解生态学，就要了解生物学的所有方面，而要做一个彻底的生物学家就是做一名生态学家。——Edward O. Wilson 

我们的研究对象涵盖小到细菌、大到鲸鱼，从个体到全球，时间尺度从一分钟至百万年，探讨生物资源生产，更关心生态环境变动和气候变化。欢迎来到海洋生态学的世界。

​招生专业：086001-生物技术与工程（海洋生物与生态方向)，详见南海所硕士招生专业目录:（http://www.scsio.cas.cn/yjsjy/zsxx/zhaosheng/）

海洋生物与生态

2007-09--2012-06   中国科学院南海海洋研究所   博士学位
2003-09--2007-06   广东海洋大学，水产学院   学士学位

   

2021-08~2022-08,德国赫姆霍兹基尔海洋研究中心, 访问学者
2016-06~2017-06,加拿大国立科学研究院，水、地与环境研究中心, 访问学者
2015-12~现在, 中国科学院南海海洋研究所, 副研究员
2014-10~2015-02,厦门大学，近海海洋环境科学国家重点实验室, 访问学者
2012-11~2013-05,香港科技大学，生命学部, 访问学者
2012-07~2015-12,中国科学院南海海洋研究所, 助理研究员

   

（ 1 ） 一种收集水生动物呼吸释放14CO2的装置及其使用方法, 发明专利, 2022, 第 3 作者, 专利号: CN112842403B

（ 2 ） 一种用于清洗纤细管道的系统, 实用新型, 2011, 第 1 作者, 专利号: CN202028574U

（ 3 ） 一种用于浮游生物的多级分选装置, 实用新型, 2011, 第 1 作者, 专利号: CN201890880U

一、发表论文情况

   2024

   52. Zhou L, Liu F, Achterberg EP, Engel A, Campbell PGC, Fortin C, Huang L, Tan Y (2024) Promoting effects of aluminum addition on chlorophyll biosynthesis and growth of two cultured iron-limited marine diatoms. Limnology and Oceanography:  http://doi.org/10.1002/lno.12558

   51. Lai Y, Tan Y, Ke Z, Zhou L, Liu J, Zhang H, Wang J, Li K, Lian X (2024) Size-dependent zoogeographical distribution of gelatinous thaliaceans associated with current velocity and temperature. Science of The Total Environment 920: 170943

   50. Liu J, Ding X, Xia X, Zhou L, Liu W, Lai Y, Ke Z, Tan Y (2024) Dissolved organic phosphorus promotes Cyclotella growth and adaptability in eutrophic tropical estuaries. Appl Environ Microbiol 90(1): e0163723

   49. Zhang Z, Zhou L, Chen X-G, Achterberg EP, Yu Y, Hathorne E, Steiner Z, Siebert C, Frank M (2024) Introduction of isotopically light barium from the Rainbow hydrothermal system into the deep Atlantic Ocean. Earth and Planetary Science Letters 625: 118476

   

   2023

   48. Zhou L*, Liu F, Tan Y*, Fortin C, Huang L, Campbell PGC (2023) Aluminum-induced changes in the net carbon fixation and carbon decomposition of a nitrogen-fixing cyanobacterium Trichodesmium erythraeum. Biogeochemistry 165: 277–290.

   47. Liu J, Zhang H, Ding X, Zhou L, Ke Z, Li J, Tan Y (2023) Nitrogen fixation under the interaction of Kuroshio and upwelling in the northeastern South China Sea. Deep Sea Research Part I 200: 104147.

   46. Yuan Z, Achterberg EP, Engel A, Wen Z, Zhou L, Zhu X, Dai M, Browning TJ (2023) Phytoplankton community response to episodic wet and dry aerosol deposition in the subtropical North Atlantic. Limnology and Oceanography 68: 2126-2140.

   45. Zhou, L., Y. Tan, and L. Huang. (2023). Coral reef ecological pump for gathering and retaining nutrients and exporting carbon: a review and perspectives. Acta Oceanologica Sinica 42(6): 1–15.

   44. 周林滨, 黄良民, 谭烨辉 (2023), 铁铝假说与海洋铝施肥增汇潜力展望, 热带海洋学报, 42(3): 1-18

   2022

   43. Liu, Q.#, Zhou, L.#, Wu, Y., Huang, H., He, X., Gao, N., & Zhang, L. (2022). Quantification of the carbon released by a marine fish using a carbon release model and radiocarbon. Marine Pollution Bulletin, 181, 113908.

   42. Liu, Q., Zhou, L.*, Zhang, W., Zhang, L., Tan, Y., Han, T., . . . Huang, H*. (2022). Rising temperature contributed to the outbreak of a macrozooplankton Creseis acicula by enhancing its feeding and assimilation for algal food nearby the coastal Daya Bay Nuclear Power Plant. Ecotoxicology and Environmental Safety, 238, 113606.

  2021

     41. Zhang H, Zhou L, Li K, Ke Z, Tan Y (2021) Decreasing biological production and carbon export due to the barrier layer: A case study in the Bay of Bengal. Frontiers in Marine Science 8(1268): 710051

40. Zhou, L., F. Liu, Q. Liu, C. Fortin, Y. Tan, L. Huang, and P. G. C. Campbell (2021), Aluminum increases net carbon fixation by marine diatoms and decreases their decomposition: Evidence for the iron–aluminum hypothesis, Limnology and Oceanography, 66(7): 2712-2727

39. Xiang, C., Z. Ke, K. Li, J. Liu, L. Zhou, X. Lian, and Y. Tan (2021), Effects of terrestrial inputs and seawater intrusion on zooplankton community structure in Daya Bay, South China Sea, Marine pollution bulletin, 167, 112331.

38. 向晨晖, 刘甲星, 柯志新, 周林滨, 谭烨辉 (2021), 大亚湾浮游植物粒级结构和种类组成对淡澳河口水加富的响应, 热带海洋学报, 40(2), 49-60

2020

   37. Liu, J., L. Zhou, Z. Ke, G. Li, and Y. Tan (2020), Phosphorus deficiency induced by aluminum in a marine nitrogen-fixing cyanobacterium Crocosphaera watsonii WH0003,  Chemosphere, 246, 125641.

36. Liu, J., L. Zhou, J. Li, Y. Lin, Z. Ke, C. Zhao, H. Liu, X. Jiang, Y. He, and Y. Tan (2020), Effect of mesoscale eddies on diazotroph community structure and nitrogen fixation rates in the South China Sea, Reg. Stud. Mar. Sci., 35, 101106.

2019

35. He, Q., H. Zhan, J. Xu, S. Cai, W. Zhan, L. Zhou, and G. Zha (2019), Eddy-induced chlorophyll anomalies in the western South China Sea, Journal of Geophysical Research: Oceans, 124:9487-9506

34. Li, J., Z. Chen, Z. Jing, L. Zhou, G. Li, Z. Ke, X. Jiang, J. Liu, H. Liu, and Y. Tan (2019), Synechococcus bloom in the Pearl River Estuary and adjacent coastal area–With special focus on flooding during wet seasons, Science of The Total Environment, 692, 769-783.

33. Liu, Q.#, L. Zhou#, F. Liu, C. Fortin, Y. Tan, L. Huang, and P. G. C. Campbell (2019), Uptake and subcellular distribution of aluminum in a marine diatom, Ecotoxicology and Environmental Safety, 169, 85-92.

32. 徐姗楠, 郭建忠, 陈作志, 许友伟, 周林滨, 柯志新, 李纯厚 (2019), 大亚湾鱼类生物量粒径谱特征, 中国水产科学, 26(01), 34-43.

2018

31. Liu, J#., L. Zhou#, G. Li, Z. Ke, R. Shi, and Y. Tan (2018), Beneficial effects of aluminum enrichment on nitrogen-fixing cyanobacteria in the South China Sea, Marine Pollution Bulletin, 129(1), 142–150.

30. Zhou, L., Y. Tan, L. Huang, C. Fortin, and P. G. C. Campbell (2018a), Aluminum effects on marine phytoplankton: implications for a revised Iron Hypothesis (Iron-Aluminum Hypothesis), Biogeochemistry, 139(2), 123-137.

29. Zhou, L., J. Liu, S. Xing, Y. Tan, and L. Huang (2018b), Phytoplankton responses to aluminum enrichment in the South China Sea, Journal of Inorganic Biochemistry, 181, 117-131.

28. 刘庆霞, 周林滨, 毋赟, 杨玉敏, and 张黎 (2018), 褶皱臂尾轮虫Brachionus plicatilis摄食小球藻 Chlorella sp. 的碳同化与碳排放, 生态学报, 38(18), 6768-6777.

2017

27. Li, J., X. Jiang, G. Li, Z. Jing, L. Zhou, Z. Ke, and Y. Tan (2017a), Distribution of picoplankton in the northeastern South China Sea with special reference to the effects of the Kuroshio intrusion and the associated mesoscale eddies, Science of The Total Environment, 589, 1-10.

26. Li, J., X. Jiang, Z. Jing, G. Li, Z. Chena, L. Zhou, C. Zhao, J. Liu, and Y. Tan (2017b), Spatial and seasonal distributions of bacterioplankton in the Pearl River Estuary: The combined effects of riverine inputs, temperature, and phytoplankton, Marine Pollution Bulletin 125(1-2), 199-207.

25. Lian, X., Y. Tan, L. Huang, and L. Zhou (2017), Striking taxonomic differences in summer zooplankton in the northern South China Sea:implication of an extreme cold anomaly, Acta Oceanologica Sinica, 36(10), 87-96.

24. Liu, J., L. Zhou, Y. Tan, Q. Wang, Z. Hu, J. Li, X. Jiang, and Z. Ke (2017), Distribution of reactive aluminum under the influence of mesoscale eddies in the western South China Sea, Acta Oceanologica Sinica, 36(6), 95-103.

23. 刘甲星, 周林滨, 柯志新, 李刚, 史荣君, and 谭烨辉 (2017), 铝对海洋固氮蓝藻 Crocosphaerawatsonii 生长及固氮速率的影响, 热带海洋学报, 36(2), 12-18.

2016

22. Zhou, L., Y. Tan, L. Huang, and W.-X. Wang (2016), Enhanced utilization of organic phosphorus in a marine diatom Thalassiosira weissflogii: A possible mechanism for aluminum effect under P limitation, Journal of Experimental Marine Biology and Ecology, 478, 77-85.

21. 刘甲星, 周林滨, 李刚, 谭烨辉, 刘华健, 赵春宇, 柯志新, 李佳俊, and 姜歆 (2016), 秋季南海东北部表层水体固氮及其对初级生产力贡献, 热带海洋学报, 35(5), 38-47.

20. 王军星, 谭烨辉, 黄良民, 柯志新, and 周林滨 (2016), 冬季南海南部微微型浮游植物分布及其影响因素, 生态学报, 36(6), 1698~1710.

19. 史荣君, 李志红, 周林滨, and 谭烨辉 (2016), 溶解态铝对海洋浮游植物群落结构及聚球藻生长的影响, 南方水产科学, 12(1), 1-8.

2015

18. Shi, R., G. Li, L. Zhou, and Y. Tan (2015), Increasing aluminum alters the growth, cellular chlorophyll a and oxidation stress of cyanobacteria Synechococcus sp., Oceanological and Hydrobiological Studies, 44(3), 343-351.

17. Zhou, L., Y. Tan, L. Huang, and G. Li (2015a), Does microzooplankton grazing contribute to the pico-phytoplankton dominance in subtropical and tropical oligotrophic waters?, Acta Ecologia Sinica, 35(1), 29-38.

16. Zhou, L., Y. Tan, L. Huang, Z. Hu, and Z. Ke (2015b), Seasonal and size-dependent variations in the phytoplankton growth and microzooplankton grazing in the southern South China Sea under the influence of the East Asian monsoon, Biogeosciences, 12(22), 6809-6822.

15. Zhou, L., L. Huang, Y. Tan, X. Lian, and K. Li (2015c), Size-based analysis of a zooplankton community under the influence of the Pearl River plume and coastal upwelling in the northeastern South China Sea, Marine Biology Research, 11(2), 168-179.

14. 李佳俊, 沈萍萍, 谭烨辉, 姜歆, 周林滨 (2015), 南海东北部浮游植物对氮_磷加富的响应及与不同水团的关系, 海洋学报, 37(10), 88-99.

2014

13. Hu, Z., Y. Tan, X. Song, L. Zhou, X. Lian, L. Huang, and Y. He (2014), Influence of mesoscale eddies on primary production in the South China Sea during spring inter-monsoon period, Acta Oceanologica Sinica, 33(3), 118-128.

12. 王琼, 谭烨辉, 周林滨, 柯志新, 黄良民 (2014), 南海中南部溶解态铝初探: 促进甲藻生长？, 热带海洋学报, 33(2), 78-86.

2013

11. Liu, H., Z. Hu, L. Huang, H. Huang, Z. Chen, X. Song, Z. Ke, and L. Zhou (2013), Biological response to typhoon in northern South China Sea: A case study of “Koppu”, Continental Shelf Research, 68, 123-132.

10. Zhou, L., Y. Tan, L. Huang, X. Lian, D. Qiu, and Z. Ke (2013), Size-based analysis for the state and heterogeneity of pelagic ecosystems in the northern South China Sea, Journal of Oceanography, 69(4), 379-393.

9. 柯志新, 黄良民, 谭烨辉, 周林滨, 张建林 (2013), 2008 年夏末南海北部叶绿素 a 的空间分布特征及其影晌因索, 热带海洋学报, 32(4), 51-57.

8. 连喜平, 谭烨辉, 刘永宏, 黄良民, 陈清潮, 周林滨 (2013a), 吕宋海峡浮游动物群落结构的初步研究, 生物学杂志(1), 31-35.

7. 连喜平, 谭烨辉, 刘永宏, 黄良民, 陈清潮, 周林滨 (2013b), 两种浮游生物网对南海北部浮游动物捕获效率的比较, 热带海洋学报, 32(3), 33-39.

6. 周林滨, 谭烨辉,黄良民 (2013), 微型浮游动物摄食实验——稀释法中浮游植物负生长的可能原因分析, 热带海洋学报, 32(1), 48-54.

2012

5. 邢帅, 谭烨辉, 周林滨, 连喜平,黄良民 (2012), 水体浑浊度对不同造礁石珊瑚种类共生虫黄藻的影响, 科学通报, 57(5), 348-354.

2011

4. Zhou, L., Y. Tan, L. Huang, J. Huang, H. Liu, and X. Lian (2011), Phytoplankton growth and microzooplankton grazing in the continental shelf area of northeastern South China Sea after Typhoon Fengshen, Continental Shelf Research, 31, 1663-1671.

2010

3. 宋星宇, 刘华雪, 黄良民, 谭烨辉, 柯志新, 周林滨 (2010), 南海北部夏季基础生物生产力分布特征及影响因素, 生态学报, 30(23), 6409-6417.

2. 周林滨, 谭烨辉, 黄良民, 连喜平 (2010), 水生生物粒径谱/生物量谱研究进展, 生态学报, 30(12), 3319-3333.

2009

1. 卢伙胜, 周林滨, 颜云榕, 冯波 (2009), 硇洲岛海域文昌鱼的分布与栖息底质关系, 台湾海峡 (应用海洋学学报）, 28(2), 272-278.

二、其他文章情况

1.  科普文章：周林滨 （2023），“海洋沙漠绿洲”再揭秘，中科院之声（https://mp.weixin.qq.com/s/0VH6aocSPIzX2zqtra0ppQ）

2.  科普文章：周林滨 （2021）, 海洋“铝施肥”可以给地球降温吗？, 中科院之声（https://mp.weixin.qq.com/s/4_zFeS2EZNX7Fneb1aR7nQ）

3.  预印版文章：Q. Liu#,L.Zhou#, Y. Wu, X. He, N. Gao, and L. Zhang (2020), Estimation of carbon released by mesopelagic fish in the global open ocean using a carbon release model and model fish-derived parameters, Earth and Space Science Open Archive.doi:10.1002/essoar.10503039.2

4.  会议论文： 周林滨, 谭烨辉,  黄良民 (2012), 沙尘气溶胶沉降对南海浮游植物生长影响初探, 中国海洋湖沼学会水环境分会中国环境科学学会海洋环境保护专业委员会2012年学术年会, 中国吉林延吉.