东、黄海沉积物-水界面营养盐交换速率的研究

2000年10月和2001年5月随“东方红2号”考察船在东、黄海进行考察,在A2、E2、E4、E5、E65个站位作了培养实验,研究沉积物-水界面在氧化和还原条件下的交换通量。在东海海域,NO3-、PO43-、总磷(TDP)由水向沉积物中扩散,NH4 、SiO32-由沉积物向水中扩散,NO3-、TDP、NH4 在还原条件下的交换通量大于氧化条件下的交换通量,PO43-、SiO32-在氧化还原条件下的交换通量基本一致。在黄海海域,两站位各溶解态营养盐的迁移方向有较大差异。在距离陆地较近的海域,各溶解态营养盐多由水中向沉积物中扩散,且距离陆地越近,交换通量越大。在东、黄海海域,沉积物释放的SiO32-对初级生产力的贡献分别为13%、10%~18%,与河流输送和大气沉降相比,沉积物对黄海、东海SiO32-的贡献分别占90%、86%,说明沉积物是SiO32-的源。而在整个东、黄海海域,对于溶解无机氮(DIN)和PO43-来说,它们的交换通量为负值,即沉积物从水体中吸附溶解无机氮和磷,说明沉积物是DIN和PO43-的汇。     

Pore Water Nutrient Regeneration in Shallow Coastal Bohai Sea, China

The regeneration of pore water nutrients was studied and the contribution of benthic nutrient fluxes to the overlying water was evaluated on the basis of field specific observations conducted in September–October 1998 and April–May 1999 in the Bohai Sea. Nutrient concentrations in sediment pore waters were examined by incubating sediment core samples with overlying seawater in air and/or nitrogen conditions. Nutrient diffusion fluxes calculated by diagenetic equations were within a factor of 2 during incubations. The factors affecting nutrient diffusion across sediment/water interface include bioturbation, nitrification, denitrification, adsorption, and dissolution. The regeneration of nutrients from sediments will increase nutrient loads of the Bohai Sea and affect nutrient atomic ratios in this region. Among nutrient sources from riverine input, atmospheric deposition and sediment regeneration, ammonium and phosphate mainly came from atmospheric deposition (>50%); nitrate was mainly transported by riverine input into the Sea, silicate from sediment regeneration accounts up to 60%. This demonstrates that nutrient regeneration in sediments contributes more silicate than riverine input and atmospheric deposition together, but benthic flux contributes very much less phosphate and nitrate relative to riverine input and atmospheric deposition. The benthic fluxes of nutrients may lead to a decrease of the amount of nitrate, an increase of phosphate, ammonia and silicate in the water column. The release of silicate from sediments may compensate the decrease of silicate due to the reduction of riverine discharge. Nutrient regeneration in sediment may have an important influence on the eutrophic character of coastal waters in this region. This revised version was published online in August 2006 with corrections to the Cover Date.     

用成岩模型计算沉积物-水界面营养盐的交换通量--以渤海为例

根据沉积物中营养盐的再生对水体中营养盐的收支循环动力学的作用.利用1998年秋季和1999年春季沉积物间隙水中营养盐的分析结果,建立了沉积物中营养盐的成岩模型,并由此计算了沉积物-水界面营养盐的交换通量.结果表明,硝化速率、反硝化速率、有机氮含量、硅质成分的溶解速率、生物扰动作用、孔隙率明显影响沉积物间隙水中营养盐的分布和沉积物-水界面的交换通量.对比了实验室培养法和扩散通量计算法测得沉积物-水界面营养盐的交换通量,表明2种方法所得NO3通量较一致,但NH4 ,PO43-,SiO32- 2种方法所得通量有一定差异,文中讨论了可能的原因.以渤海为例阐明了在用扩散通量法研究沉积物-水界面营养盐的交换通量时,表层沉积物分割厚度对界面交换通量影响显著,为了得到合理的与现场接近的结果表层沉积物的分割厚度以不超过1em为宜.     

黄河下游调水调沙与暴雨事件对营养盐输出通量的影响

2012年2月至2014年3月在黄河下游采集水样,分析黄河下游营养盐浓度与通量的月际、季节性以及在调水调沙期和暴雨期的变化情况,并估算了调水调沙期和洪水期输水量和营养盐入海通量对黄河年入海通量的贡献。结果表明NO₃- 是TDN的主要存在形式,各形态氮营养盐枯水期高于丰水期;DIP是TDP的主要存在形式,PIP是TPP的主要存在形态,颗粒态磷和DSi丰水期高于枯水期。黄河水体中具有高DIN/DIP和DSi/DIP,低DSi/DIN,严重偏离Redfield比值。营养盐输送通量具有很强的月际变化,在径流量及输沙量最大月份也存在营养盐入海通量峰值。2002-2012年10年间调水调沙和暴雨在营养盐输送通量上占黄河下游营养盐输送通量的23%~68%和5%~59%,对营养盐年入海通量的平均贡献分别为 38%和24%,二者均在短期内导致水、沙和营养盐的大量输送,将对黄河口及其邻近海域的生态环境产生重要的影响。     

桑沟湾养殖海域营养盐和沉积物-水界面扩散通量研究

利用2006年4,7,11月和2007年1月4个航次对桑沟湾养殖海域的观测资料,分析了该海域营养盐分布、结构特征、主要控制过程以及沉积物-水界面扩散通量,结果表明,该海域的营养盐分布具有明显的季节变化,海水中NO3-,NO2-,PO43-,DOP,TDP和SiO32-浓度皆是秋季最高,而NH4+,DON,TDN浓度则为夏季最高;各种营养盐的最低值除DON外都出现在春季。春季湾内外海水交换不畅,再加上大型藻类海带等生长旺盛期的消耗,使营养盐浓度处于较低水平,在夏秋两季丰水期沿岸河流注入对该海域营养盐的影响较大,冬季无机营养盐浓度分布主要受沿岸流的影响。磷的结构变化较大,其中DOP百分含量在夏季最高,达到81%。从春季到秋季海水中TDN的结构变化从以DON为主转变成以DIN为主。硅和氮的原子比值全年变化不大,硅和氮和氮和磷原子比值春夏两季的高于秋冬季的。分析营养盐化学计量限制标准和浮游植物生长的最低阈值结果表明,磷是春夏两季桑沟湾浮游植物生长的限制性因素;春季硅浓度低于浮游植物生长的最低阀值,也是一个潜在的限制因素。计算结果显示桑沟湾沉积物释放的NH4+,SiO32-和PO43-对初级生产力的贡献较小,与其他浅海环境相比,桑沟湾沉积物-水界面的营养盐通量处于较低或中等水平。     

Seasonal variations of dissolved organic matter and nutrients in sediment pore water in the inner part of Tokyo Bay

At four stations in Tokyo Bay, pore water profiles of dissolved organic carbon (DOC), nitrogen (DON), phosphorus (DOP), and inorganic nutrients were determined at 3-month intervals over 6 years. Concentrations of dissolved organic matter (DOM) and nutrients were significantly higher in pore waters than in the overlying waters. Pore water DOC, DON, and DOP concentrations in the upper most sediment layer (0–1 cm) ranged from 246 to 888 μM, from 14.6 to 75.9 μM, and from 0.02 to 9.83 μM, respectively. Concentrations of DOM and nutrients in pore waters occasionally showed clear seasonal trends and were highest in the summer and lowest in the winter. The seasonal trends in the pore water DOM concentrations were coupled with trends in the overlying water temperature and dissolved oxygen concentration. Benthic effluxes of DON and DOP were low compared with those of inorganic nutrients, accounting for only 1.0 and 1.5 % of the total benthic effluxes of nitrogen and phosphorus, respectively; thus benthic DOM fluxes were quantitatively insignificant to the inorganic nutrient fluxes in Tokyo Bay. The DOM fluxes represented about 7, 3, and 10 % of the riverine discharge of DOC, DON, and DOP to Tokyo Bay, respectively.     

南海水体三项无机氮含量的垂直变化特征及与其他环境要素的相关性

据南海环境调查资料，研究了南海水体NO3-N、NO2-N、NH4-N、DIN含量及无机氮组成的垂直变化规律．结果表明：NO3-N、NO2-N、NH4-N、DIN含量范围和均值分别为0．00～43．9，12．32；0．00～1．69，0．07；0．17-14．87，1．32；0．35～45．92，13．73μmol／dm^3．其含量分布与垂直变化特征与深海、大洋的相似，表明南海水是太平洋的变性水体．NO3-N、DIN含量的垂直分布跃层出现于75～500m间，夏季的跃层强度分别为6．61X10-’、6．68×1012Ixmol／（dm’·m），冬季的均为5．65×10^-2μmol／（dm^3·m）；NO2-N含量的最大值多出现于75～100m之间，NH4-N含量的最大值出现在0m层．在浮游植物活动较旺盛的真光层中，NH4-N为无机氮的主要存在形态（平均占比为64．4％）．真光层以下NO3-N为无机氮的主要存在形态（平均占比≥90．8％）．对三项无机氮含量与其他生源要素、水文因子的相关分析结果表明，NO3-N含量与PO4-P、TDP、TP、SiO3-Si、S均呈显著正相关，与pH、DO、O2％、t则呈显著负相关．     

Annual Variation of Benthic Nutrient Fluxes in Shallow Coastal Waters (Gulf of Trieste, Northern Adriatic Sea)

Abstract. Benthic fluxes of dissolved N. Si and P nutrients, alkalinity, dissolved inorganic C (DIC), and O₂ from sediments in the Gulf of Trieste (northern Adriatic, Italy) were measured monthly for 16 months, using laboratory incubated flux chambers at in siru temperatures in the dark. The annual average fluxes were: 02 = -19.3 ± 8.2, DIC = 13.7 ± 9.6, NO3 = -0.04 ± 0.16, NH4 = 0.3 ± 0.4. PO₄= 4.001 ± 0.01, Si = 0.9 ± 0.1 mmol m-² d^-1, with strong temporal fluctuations. The highest effluxes of all nutrients and DIC were observed in the summer. Small effluxes of DIC and NH4 and influxes of Si and PO4 were observed in late winter. Only NH₄ (ca. 50%) and Si (ca. 70%) fluxes were significantly correlated with temperature. This correlation suggests that the rate of downward input and the quality of sedimented organic matter (autochthonous and allochthonous) were superimposed on the temperature fluctuations. High DIC, NH₄ and Si effluxes observed in May 1993 during low temperature were due to the degradation of sedimentary organic matter produced by an early spring bloom of benthic microalgae which occurred about 6 weeks earlies while the autumn phytoplankton bloom was simultaneously reflected in enhanced benthic fluxes due to higher temperature. The role of benthic biological advection in this transport across the sediment-water interface, evaluated by comparison between measured benthic and calculated diffusive fluxes from nutrient pore water concentrations, was of minor importance. This is probably due to low infaunal activity throughout the year it was localized mostly in the narrow surficial layer. The annual average diffusive fluxes of NH4 and PO4 were higher than those measured, probably due to the presence of nitrificationdenitrifi-cation processes and redox-dependent chemical reactions at the oxic sediment-water interface, respectively. Only during bottom-water hypoxia in September 1993 did strong PO₄ effluxes prevail. Calculations based on the Redfield stoichiometry of oxic decomposition of organic N to NH4 and NO3, and differences between diffusive and measured NH₄ fluxes showed that denitrifkation averaged 0.8 mmol m^-2 d^-1. Significant correlations between NH₄ and PO₄ DIC and Si, and NH4 and Si fluxes suggested their parallel regeneration and utilization at the sediment-water interface. The nutrient fluxes observed were not significantly linked to O₂ consumption, suggesting also that anaerobic oxidation processes were important at the sediment-water interface in the gulf. The N, P and Si nutriqnts released from sediment pore waters are probably utilized in benthic microalgal and bottorn-hater primary production. This indicates that pelagic and benthic communities in the central part of the Gulf of Trieste function relatively independently of each other.     

Historic changes in flux of matter and nutrient budgets in the Bohai Sea

Over the past four periods （ 1959--1960, 1982--1983, 1992--1993, and 1998--1999）, the ecosystem of the Bohai Sea changed due to both a significant decrease of river water discharge from the Huanghe River and a reduction of precipitation. The shifts in nutrient chemistry could result in changes in the phytoplankton composition with an increased potential for non-diatom algal blooms. Simple box model was used to estimate the water - mass balance and nutrient budgets for the Bohai Sea. Water budgets indicate that the residual flow changed from out of the Bohai Sea before 1993, but became inflow to the Bohai Sea after then. The nutrient budgets developed indicate that the Bohai Sea was a sink for nutrients except for phosphate in 1959--1960 and 1982-- 1983 and for silicate in 1982--1983. Net water flow transports nutrients out of the Bohai Sea in 1959--1960, 1982--1983 and 1992--1993, but into the sea in 1998--1999 due to climate changes, such as precipitation and subsequent freshwater discharge. The residual fluxes of nutrients are minor relative to atmospheric deposition and riverine inputs. Conversions of phosphate values to carbon by stoichiometric ratios were used to predict that the system was net heterotrophic before 1982--1983 and net autotrophic after then. Nutrient budgets can explain the change of nutrient concentrations in the Bohai Sea except nitrates, which should include the surface runoff.     

大亚湾湿地底栖微藻对氮素的吸收存储及影响因素探究

为探讨不同类型湿地表层沉积物中底栖微藻对氮素的吸收存储能力及其影响因素,于 2017 年 3 月（枯水期） 和 8月 （丰水期） 分别采集大亚湾光滩湿地 （T1）、河口湿地 （T2） 和红树林湿地 （T3） 表层沉积物底栖微藻样品,并进行了反复冻融实验。研究结果表明,大亚湾滨海湿地表层沉积物中的底栖微藻丰度具有显著的时空差异,温度、营养盐和沉积物粒径可能是影响底栖微藻生长繁殖的主要因素。不同季节比较发现,底栖微藻的氮累积存储能力表现为枯水期强于丰水期,主要由于丰水期较高温度和强光照引起的过度干燥和光刺激,限制了底栖微藻的生长繁殖。河口湿地丰富的营养物质能促进底栖微藻的生长繁殖,致使在淡澳河河口湿地叶绿素含量最高,底栖微藻丰度也最大。底栖微藻胞内溶解无机氮 （DIN） 含量表现为T2（河口湿地） >T1（光滩湿地） >T3（红树林湿地） 的空间分布特征,这与其生物量的时空分布特征相一致 （P<0.01）,并且底栖微藻对氨氮 （NH4-N） 有较强的累积存储能力,胞内氨氮 （IC-NH4） 在胞内无机氮 （IC-DIN） 高达90.8%。底栖微藻 IC-DIN 占整个沉积物氮库的 24.2%,其中约 20.0% 的 NH4-N、17.6% 的 NO3-N 和 16.0% 的NO2-N被吸收累积在底栖微藻细胞内。整体上,大亚湾湿地沉积物底栖微藻的氮素累积能力受营养负荷的影响,且NH4-N负荷越高,底栖微藻对氮的吸收存储能力越强,能有效降低近岸富营养化水平。     

南大洋沉积物间隙水中营养盐分布及扩散通量研究

利用中国第18次南极考察获得的沉积物样品,对南大洋沉积物间隙水中营养盐的含量及分布特征进行了研究,估算了营养盐的底部通量.结果表明,南大洋沉积物间隙水中的营养盐以高含量的硅酸盐、铵盐为主.在垂向分布上,硅酸盐在沉积物-水界面呈现出明显的浓度梯度,这种分布特征表明,在硅的早期成岩过程中溶出是主要过程.沉积物中有机物的降解反应主要在还原状态下进行.硅酸盐与铵盐存在明显的向上释放的通量.     

The influence of long emersion on biota, ammonium fluxes and nitrification in intertidal sediments of Marennes-Oléron Bay, France

A comparative study between waterlogged and reflooded intertidal sediments was undertaken in March and June 1999 through statistical analysis of selected sediment parameters (biota, salinity, O2, Eh), pool sizes and benthic fluxes of nutrients (NH4+, NO2-, NO3-) and nitrification rates. In March samples, absence of polychaetes and oligochaetes from upper sediment horizons were due to erosional events sweeping away surface sediments. Presence of richer annelid assemblages in June samples indicated more stable hydrodynamic conditions that favoured the development of benthic microalgae biofilms. Dewatering of sediments during a 3-day emersion period promoted a salinity rise on top layers, migration of pore water ions towards the sediment surface, and created sediment fissures that accelerated water exchange on reflooding. Reflooded and waterlogged sediment systems were comparable with respect to the release of NH4+ to overlying water but were different with respect to nitrification rates. Sediment-water NH4+ fluxes were higher (P = 0.011) in March (3.3 mmol m(-2) day(-1) compared to June (1.4 mmol m(-2) day(-1) due to higher macrofauna biomasses and lower benthic microalgae concentrations in March samples. Potential nitrification rates (range from 19 to 60 mmol NO3- (-2) day(-1)) were not statistically different between March and June. A thinner oxic layer in reflooded compared with waterlogged systems reflects a decrease of O2 diffusion into sediment at high salinities which resulted in the fall of the actual nitrification rates (P < 0.05). Our data suggest that long term dessication of intertidal sediments may depress the nitrification process at the ecosystem level.     

乳山湾外邻近海域氮和磷的分布与收支过程研究

基于2009年6–9月，2014年5月，2014年7–8月在乳山湾外邻近海域的综合调查资料，分析了该开放海域水体与沉积物中氮、磷营养盐的组成和分布，并在潮汐潮流数值模式计算水通量的基础上分析了近岸开放区域无机氮(DIN)和无机磷(DIP)的循环与收支的主要过程，量化了潮汐潮流、初级生产的消耗与转化、底界面过程与内部循环等过程对氮和磷营养盐循环与收支的影响。结果表明，夏季乳山湾外邻近海域水体DIN和DIP的浓度与分布受陆源输入和潮汐潮流的共同影响，高值均出现在湾口区域；沉积物-水界面存在DIN和DIP从沉积物向上覆水释放的现象，使得底层水体的氮、磷营养盐浓度高于表层水体。氮的收支表明，研究海域水体内部循环过程是初级生产所需DIN的主要来源，占初级生产总消耗量的86%，其次是水交换作用(11%)，底界面扩散对初级生产的贡献相对较小(3%)；水体DIN的移出主要是通过埋藏、向外海的输送和水体反硝化作用，其比例分别为80%、16%和4%。磷的收支显示，研究海域水体内部循环过程贡献了初级生产所需DIP的91%，其次是水交换作用(9%)，底界面扩散对初级生产的贡献小于1%；水体DIP支出主要是通过沉积埋藏和向外海的输送，其比例分别为67%和33%。研究结果表明内部循环过程是近海水体氮和磷获得补充的主要途径，不过外部来源的氮、磷营养盐结构与系统内部具有显著的差异，且系统内磷的埋藏效率要高于氮，其必将对乳山湾外邻近海域营养盐结构和初级生产产生长远的影响。     

浙江南麂列岛海域氮、磷营养盐季节动态及其环境影响因子分析

利用南麂海域4个站位2006年4月至2007年3月的连续调查资料,研究了该海域氮、磷营养盐的季节变化特征及其影响因素.南麂海域的无机氮主要由硝酸盐构成,平均占有比例77%.氮、磷营养盐的季节性变化显著,并且两者呈现同步的上升或下降的趋势.PO4-P 与 NO3-N 的相关性显著 ( r = 0.665 ).NO3-N 与水温、pH、盐度等多项因子之间均具有显著的相关性,其中与水温的相关性最为密切 ( r = 0.798 ).     

黄河下游营养盐浓度、入海通量月变化及“人造洪峰”的影响

于2009年至2011年在黄河下游采集溶解及颗粒态营养盐样品,分析了黄河下游各形态营养盐的浓度变化及营养盐入海通量,结果表明各形态氮的浓度多呈丰水期低、枯水期高,溶解无机氮是溶解态氮的主要存在形式;受黄河高悬浮颗粒物含量的影响,磷以颗粒态占绝对优势,而溶解态磷以溶解无机磷为主要存在形态;生物硅的含量平均约占硅酸盐与生物硅之和的20％,硅的浓度丰水期高于枯水期.颗粒态磷与生物硅的含量与悬浮颗粒物含量呈正相关.营养盐的组成具有高氮磷比、高硅磷比、低硅氮比的特点.近年来黄河下游溶解无机氮浓度显著升高而溶解无机磷变化不大,硅酸盐的浓度有所下降.黄河下游水沙通量、营养盐入海通量有明显的季节变化,丰水期占全年总入海通量的42％～84％.调水调沙期间,各营养盐的浓度和组成均有明显变化,氮的浓度、DIN/PO4-P下降,磷与硅的浓度、SiO3-Si/DIN、SiO3-Si/PO4-P升高,颗粒态营养盐的比例明显增加.短期内大量水沙及营养盐入海通量对黄河口及渤海生态系统产生重要影响.     

黄、渤海无机氮的收支模式初探

根据黄、渤海无机氮的收支状况，首次提出了黄、渤海无机氮的稳态收支模式。模式研究结果表明，大气沉降、陆源输入和海底输入的无机氮通量分别占黄、渤海无机氮浮游植物总需求量的3%、4%和12%。无机氮的外部输入约占总需求量的1/5，其他部分则由水柱中的内部再循环（再生）供给。     

长江河口淡水端溶解态无机氮磷的通量

1998年2和9月在长江河口淡水端连续观测了DIN(NO₃-,NO₂-,NH₄+),PO₄3-,流速和流向.结果表明,溶解态无机氮、磷浓度的时空变化较复杂;1998年2月NO₃-,NO₂-,NH₄+和PO₄3-的月通量分别为168241,974.4,19335和2648t,9月的月通量分别为905678,8317,5797和6281t;1998年NO₃-,NO₂-,NH₄+和PO₄3-年通量分别为497.1×104,3.911×104,10.22×104和4.155×104t.     

西北太平洋楚科奇海沉积物-水界面营养盐输送通量估算

陆架区沉积物间隙水的营养盐再生是水体营养盐补充的重要途径之一。楚科奇海陆架区中部沉积物间隙水中的营养盐分布,是物理和生物扰动较弱状态下的沉积物-水界面的典型分布。本文对中国第4次北极科学考察采集的4个多管短柱沉积物样品及多管样站位的上层水样进行分析,得到沉积物间隙水、上覆水以及水柱中营养盐数据。结果表明,沉积物间隙水各营养盐浓度均先随沉积深度增加而呈指数快速升高,记为Ⅰ层;然后进入沉积物再矿化作用与营养盐移出速率相互抵消的稳定变化层,营养盐浓度在该阶段基本不变,记为Ⅱ层;最后是营养盐缓慢递减层,记为Ⅲ层,由于该层有机质降解作用耗尽氧气,NO-3和PO3-4被还原细菌利用而失去氧离子。通过双层模式和Fick第一扩散定律,计算得出楚科奇海沉积物-水界面硅酸盐、磷酸盐和硝酸盐的扩散通量分别为1.660mmol/(m2·d)(以Si计量)、0.008mmol/(m2·d)(以P计量)、0.117mmol/(m2·d)(以N计量)(以R06站为例)。四个调查站位沉积物中硅酸盐的扩散通量分别为3.101mmol/(m2·d)(以Si计量,CC1站)、1.660mmol/(m2·d)(以Si计量,R06站)、1.307mmol/(m2·d)(以Si计量,C07站)、0.243mmol/(m2·d)(以Si计量,S23站),含量呈现明显的纬度分布特征。沉积物间隙水N*的分布表明,楚科奇海沉积环境具有很强的反硝化过程,沉积物脱氮作用是硝酸盐一个重要的汇。     

象山港大黄鱼Pseudosciaena crocea网箱养殖区沉积物-水界面营养盐通量研究

2013年5月、8月和11月调查了象山港大黄鱼网箱养殖区及附近沉积物中总有机氮(TON)、总有机碳(TOC)和总磷(TP)含量,并采用实验室模拟法研究了底泥耗氧率(SOCs)和沉积物-水界面营养盐(NH⁺₄、NO^-₂+NO^-₃和PO^3-₄)通量。结果表明:养殖区(YZ)沉积物中的TON和TP含量显著高于距离养殖区50 m(F1)和100 m(F2)的区域(P<0.05)。底泥释放NH⁺₄到上覆水中,但是从上覆水中吸收NO^-₂+NO^-₃和PO^3-₄。沉积物-水界面营养盐通量表现出明显的季节性变化,在8月,NH⁺₄及PO^3-₄的释放量达到最大值。上覆水中NH⁺₄、NO^-₂+NO^-₃和PO^3-₄的质量浓度随着沉积物-水界面营养盐通量的变化而变化。研究表明,象山港大黄鱼养殖活动对养殖区底泥造成了一定污染,且通过影响沉积物-水界面营养盐通量影响上覆水中营养盐分布,最终给整个养殖系统造成生态负担。