闽江下游水体硅的组成及营养盐化学计量比

doi:10.13287/j.1001-9332.202308.028

摘要/Abstract

摘要： 在过去几十年里,河流在人类活动的影响下向沿海生态系统输送不平衡的营养盐负荷导致了严重的区域或全球富营养化问题。闽江受人类活动影响比较明显,为了研究闽江水体营养盐输送比例的变化特征,于2019年7月至2020年7月对闽江下游表层水体碳、氮、磷、硅营养盐进行了季节观测。结果表明: 闽江下游表层水体溶解态硅(DSi)、成岩硅(LSi)和生物硅(BSi)的年平均含量分别为5.30、4.58和2.37 mg·L^-1,但季节性差异大,夏季表现为溶解态硅>成岩硅>生物硅,秋季为溶解态硅>生物硅>成岩硅,而冬季为成岩硅>溶解态硅>生物硅。其中溶解态硅在总硅中的比例沿向海方向呈逐渐降低趋势,而生物硅与之相反。从化学计量比来看,闽江水体明显地受碳、磷限制,基本不受硅、氮限制。据估算,闽江每年向河口输送1.03×10¹⁰ mol溶解态硅和0.46×10¹⁰ mol生物硅,并且呈现逐年下降趋势,而碳、氮、磷负荷则呈上升趋势,这种营养盐比例关系会导致河口及近海生态系统结构和功能发生变化。研究闽江水体碳、氮、磷、硅营养盐的化学计量比可为闽江河口及邻近海域水体营养盐结构平衡和富营养化等问题的解决提供理论依据。

关键词: 硅组分, 化学计量比, 通量, 闽江下游

Abstract: Over the past decades, rivers have delivered imbalanced nutrient loads to coastal marine ecosystems due to human activities, which leads to serious regional or global eutrophication problems. The Minjiang River is heavily influenced by human activities. To understand the changing characteristics of nutrient transport ratios in the Minjiang River waters, we measured the seasonal variations of carbon, nitrogen, phosphorus and silicon nutrients in the lower surface waters of the Minjiang River between July 2019 and July 2020. The results showed that the annual average contents of dissolved silicon (DSi), lithogenic silicon (LSi) and biogenic silicon (BSi) in the surface waters of the lower Minjiang River were 5.30, 4.58 and 2.37 mg·L^-1, respectively. There were large seasonal differences among these parameters, with higher content of DSi than LSi and BSi in summer, higher content of DSi than BSi and LSi in autumn and higher content of LSi than DSi and BSi in winter. The proportions of DSi in total silicon tended to decrease gradually from land to sea, while the proportion of BSi was on the contrary. In term of stoichiometric ratios, the Minjiang River mostly presented carbon or phosphorus limitation and was unlimited by silicon or nitrogen. About 1.03×10¹⁰ mol DSi and 0.46 ×10¹⁰ mol BSi were delivered via the Minjiang River to the ocean yearly, showing a decreasing trend year by year. Based on the data in recent years, the nutrient loads of carbon, nitrogen, and phosphorus transported by Minjiang River showed an increasing trend. The imbalanced nutrient loads may lead to changes in the structure and function of the river, estuary, and offshore ecosystems. The study of nutrient stoichiometric ratios can provide a theoretical basis for solving the problems in structural balance of nutrients and eutrophication in Minjiang River estuary and adjacent marine waters.

Key words: silicon component, stoichiometric ratio, flux, lower reaches of the Minjiang River.

刘佳妮, 翟水晶, 邱思婷, 俞新慧, 王赛. 闽江下游水体硅的组成及营养盐化学计量比[J]. 应用生态学报, 2023, 34(8): 2205-2214.

LIU Jiani, ZHAI Shuijing, QIU Siting, YU Xinhui, WANG Sai. Silicon composition and stoichiometric ratios with other nutrients in the lower Minjiang River, Southeast China[J]. Chinese Journal of Applied Ecology, 2023, 34(8): 2205-2214.

参考文献

[1] Tréguer P, Nelson DM, Van Bennekom AJ, et al. The silica balance in the world ocean: A reestimate. Science, 1995, 268: 375-379
[2] 曹璐, 刘素美, 李瑞香. 春季长江口及邻近海域悬浮颗粒态硅的研究. 海洋学报, 2011, 33(1): 83-90
[3] Amann T, Weiss A, Hartmann J. Silica fluxes in the inner Elbe Estuary, Germany. Biogeochemistry, 2014, 118: 389-412
[4] 王昊, 冉祥滨, 臧家业, 等. 长江与黄河入海活性硅输送规律及变化趋势. 湖泊科学, 2018, 30(5): 1246-1259
[5] Ran X, Liu S, Liu J, et al. Composition and variability in the export of biogenic silica in the Changjiang River and the effect of Three Gorges Reservoir. Science of Total Environment, 2016, 571: 1191-1199
[6] Viaroli P, Nizzoli D, Pinardi M, et al. Factors affecting dissolved silica concentrations, and DSi and DIN stoichiometry in a human impacted watershed (Po River, Italy). Silicon, 2013, 5: 101-114
[7] Conley DJ. Riverine contribution of biogenic silica to the oceanic silica budget. Limnology and Oceanography, 1997, 42: 774-777
[8] Liu SM, Hong GH, Zhang J, et al. Nutrient budgets for large Chinese estuaries and embayment. Biogeosciences, 2009, 6: 2245-2263
[9] 俞洋, 汤显强, 王丹阳, 等. 长江流域水体硅含量分布特征及影响因素研究综述. 长江科学院院报, 2022, 39(3): 38-46
[10] Chai C, Yu ZM, Shen ZL, et al. Nutrient characteristics in the Yangtze River Estuary and the adjacent East China Sea before and after impoundment of the Three Gorges Dam. Science of the Total Environment, 2009, 407: 4687-4695
[11] Garnier J, Beusen A, Thieu V, et al. N:P:Si nutrient export ratios and ecological consequences in coastal seas evaluated by the ICEP approach. Global Biogeochemical Cycles, 2010, 24, doi:10.1029/2009gb003583
[12] 中华人民共和国国家标准. 海洋监测规范第4部分: 海水分析. GB 17378.4—2007. 北京: 中国标准出版社, 2007
[13] 杨玉珍, 夏未铭, 杨瑾, 等. 水体中叶绿素a测定方法的研究. 中国环境监测, 2011, 27(5): 24-27
[14] Ragueneau O, Savoye N, Del Amo Y, et al. A new method for the measurement of biogenic silica in suspended matter of coastal waters: Using Si:Al ratios to correct for the mineral interference. Continental Shelf Research, 2005, 25: 697-710
[15] 李延伟, 刘素美, 朱卓毅, 等. 万泉河口悬浮颗粒态磷和硅的分布特征及收支估算. 海洋学报, 2011, 33(6): 180-188
[16] 叶翔, 陈坚, 暨卫东, 等. 闽江口营养盐生物地球化学过程研究. 环境科学, 2011, 32(2): 375-382
[17] 刘四光, 高爱国, 陈岚, 等. 闽江河口咸淡水混合过程中营养盐含量的变化特征. 台湾海峡, 2012, 31(3): 49-56
[18] Burton JD, Liss PS. Progress of supply and removal of dissolved silicon in the oceans. Geochimica et Cosmochimica Acta, 1973, 37: 1761-1773
[19] Bien GS, Contois DE, Thomas WH. The removal of solu-ble silica from fresh water entering the sea. Geochimica et Cosmochimica Acta, 1958, 14: 35-54
[20] 郭劳动, 郭锦宝, 李法西. 河口硅酸盐物理化学过程研究. V. 河口硅酸盐吸附形成自生矿的模拟实验. 海洋学报, 1983, 5(2): 172-177
[21] Lawson DS, Hurd DC, Pankratz HS. Silica dissolution rates of decomposing phytoplankton assemblages at various temperatures. American Journal of Science, 1978, 278: 1373-1393
[22] 林培梅. 北部湾海域硅的分布与赋存形态研究. 硕士论文. 厦门: 厦门大学, 2008
[23] Chen NW, Wu YQ, Wu JZ, et al. Natural and human influences on dissolved silica export from watershed to coast in Southeast China. Journal of Geophysical Research: Biogeosciences, 2014, 119: 95-109
[24] 杨伟华, 郝倩, 夏少攀, 等. 湖泊-流域系统硅循环及其对碳和养分循环的影响. 生态学杂志, 2018, 37(3): 624-633
[25] 冉祥滨, 车宏, 臧家业, 等. 黄河流域硅的组成与输出. 中国科学: 地球科学, 2015, 45(7): 982-993
[26] 梁洲, 潘扬航, 祝嗣腾, 等. 长江口邻近海域总悬浮颗粒物的时空分布及其影响因素. 厦门大学学报: 自然科学版, 2020, 59(增刊1): 50-55
[27] Cid Bastos ATC, Santis Braga E. Different silicon forms sinalize an input of urbanized river and indicate the pre-sence of phytoplankton with silicon structures in the tropical coastal area of Recife (PE-Brazil). Brazilian Journal of Oceanography, 2018, 66: 104-114
[28] Huang YB, Mi WJ, Hu ZY, et al. Effects of the Three Gorges Dam on spatiotemporal distribution of silicon in the tributary: Evidence from the Xiangxi River. Environmental Science and Pollution Research, 2019, 26: 4645-4653
[29] Redfield AC, Ketchum BH, Richards FA. The influence of organisms on the composition of seawater. The Sea, 1963, 2: 26-77
[30] 曲克明, 陈碧鹃, 袁有宪, 等. 氮磷营养盐影响海水浮游硅藻种群组成的初步研究. 应用生态学报, 2000, 11(3): 445-448
[31] 王允, 张红梅, 吴念, 等. 黄河下游营养盐浓度月际变化及其对水库泄洪事件的响应. 中国海洋大学学报: 自然科学版, 2022, 52(3): 88-98
[32] Rabouille C, Conley DJ, Dai MH, et al. Comparison of hypoxia among four river-dominated ocean margins: The Changjiang (Yangtze), Mississippi, Pearl, and Rhone rivers. Continental Shelf Research, 2008, 28: 1527-1537
[33] Justić D, Rabalais NN, Turner RE, et al. Stoichiometric nutrient balance and origin of coastal eutrophication. Marine Pollution Bulletin, 1995, 30: 41-46
[34] 李兆喜, 高扬, 陆瑶, 等. 鄱阳湖流域多尺度碳、硅输送特征及其对浮游植物分布的影响. 生态学报, 2020, 40(19): 7073-7083
[35] 陈小霞, 冯美霞, 林雅逢, 等. 闽江原厝水源地浮游植物群落结构及其与环境因子的关系. 海峡科学, 2020(12): 31-34
[36] 侯昱廷, 高爱国, 林建杰, 等. 闽江河口营养盐的季节变化及混合行为. 厦门大学学报, 2016, 55(4): 540-546
[37] 邹栋梁, 高淑英. 闽江口溶解态镉、铜、铅的行为及其与营养盐的关系. 热带海洋, 1996, 15(1): 74-79
[38] 刘丛强, 汪福顺, 王雨春, 等. 河流筑坝拦截的水环境响应——来自地球化学的视角. 长江流域资源与环境, 2009, 18(4): 384-396
[39] 龚松柏. 闽江下游及河口区碳和COD的输运与转化. 硕士论文. 厦门: 厦门大学, 2018
[40] 钱伟, 陈莹, 杨柳明, 等. 闽江下游不同碳组分及其通量特征. 环境科学研究, 2019, 32(4): 647-653
[41] 许清辉, 郭廷宗, 林峰, 等. 闽江口无机氮营养盐的行为及入海通量. 厦门大学学报, 1991, 30(6): 632-634
[42] 孙敬慧. 我省主要河流入海通量估算. 福建环境, 1997(1): 17-18
[43] 郑小宏. 闽江口海域氮磷营养盐含量的变化及富营养化特征. 台湾海峡, 2010, 29(1): 42-46
[44] 刘洁, 郭占荣, 袁晓婕, 等. 胶州湾周边河流溶解态营养盐的时空变化及入海通量. 环境化学, 2014, 33(2): 262-268
[45] Li SY, Bush RT. Rising flux of nutrients (C , N, P and Si) in the lower Mekong River. Journal of Hydrology, 2015, 530: 447-461
[46] Jossette G, Leporcq B, Sanchez N, et al. Biogeochemical mass-balances (C, N, P, Si) in three large reservoirs of the Seine Basin (France). Biogeochemistry, 1999, 47: 119-146