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1.
It have been measured the denitrification rates (DR) of sediment in Saginaw Bay, Lake Huron, by N2 production method. Triplicate samples of sediment core were collected at two GLERL long-term monitoring sites of the Bay in July and August of 1995. The DR are 48.81 -24.99 and 32.81-40.51 micromol N2 -2h-1 in the Inner and Outer regions of Saginaw Bay, respectively.The characters of DR in Saginaw Bay were studied also in this paper. The DR were influenced by the interactions between the Saginaw River as a main pollution source and the Lake Huron as a reservoir of high quality water. The impacts of zebra mussels (Dreissena Polymorpha) on denitrification in Saginaw Bay, Lake Huron, were discussed, Significant differences in NH4+ exchange fluxes were detected in the inner and outer bays. The molar ratios of N2:TIN were similar at both sampling sites. Measured DR were positively correlated to O2 consumption rates in the headspace. Additionally, a negative correlation between NH4+ and NO3- concentrations in the overlying water was found. 相似文献
2.
不同水生植物对富营养化水体无机氮吸收动力学特征 总被引:3,自引:2,他引:1
采用浓度梯度法,研究了鸢尾(Iris louisiana)、狐尾藻(Myriophyllum verticillatum)、茭白(Zizania latifolia)和水芹(Oenanthe clecumbens)对硝态氮(NO3--N)和铵态氮(NH4+-N)吸收动力学特征.结果表明:4种水生植物对水体NO3--N和NH4+-N吸收可用Michaelis-Menten酶动力学方程描述,随溶液NO3--N和NH4+-N浓度增加,植物吸收NO3--N和NH4+-N速率增加,当溶液NO3--N和NH4+-N浓度接近于2.0 mmol/L时,吸收速率增加趋缓;4种水生植物对NO3--N和NH4+-N的Vmax值大小为水芹 >茭白 >鸢尾 >狐尾藻,对NO3--N的Km值大小为水芹 >鸢尾=茭白=狐尾藻,对NH4+-N的Km值大小为水芹 >狐尾藻 >茭白=鸢尾.根据吸收动力学参数(Vmax,Km)判断水芹适宜于净化NO3--N和NH4+-N浓度较高的水体,茭白、鸢尾和狐尾藻适合净化NO3--N和NH4+-N浓度较低水体;4种水生植物对NO3--N、NH4+-N表现出不同的吸收偏好性,鸢尾吸收NO3--N的潜力大于吸收NH4+-N的,但对NH4+-N的亲和力大于NO3--N,表明能在NO3--N浓度较高环境中优先吸收NH4+-N.狐尾藻和水芹对NO3--N和NH4+-N能均衡吸收.茭白对NH4+-N具有较高的吸收潜力与亲和力. 相似文献
3.
An avenue to integrate theoretical, experimental and field research methods to forecast water quality in water bodies for different scenarios of water management is proposed. Exploration of the laws of organization, stability and controllability of laboratory "ideal" water microbial communities (model ecosystems) is the basis to build the following biophysical research chain:to formalize with primary field information a conceptual block-diagram of a water ecosystem →to real chemical and other density-dependent and population-growth-controlling factors → to find our limiting factors for natural ecosystems → to conduct experiments with isolated chemical factors and hydrobionts to derive kinetic dependencies and quantitative parameters→ to transfer regularities of operation and kinetic dependencies to the natural ecosystem→ retrospective verification of the model on the base of available field and derived theoretical-experimental data →prognostic calculations for the scenario. Efficiency of the approach is demonstrated in microalgal "blooming" models for Krasnoyarsk and Kantat reservoirs and in prognostication of radioecological state of great Yenisei river:1) radionuclide distribution in the Yenisei''s bottom sediment is nonuniform-"spotty"; 2) it is theoretically shown, that due to biological interactions and tro-phical radioniclide migration there is "spotive" type of space radionuclide distribution. The research is to make use of the novel methods of ecological biophysics:Monitoring:spectral analysis of surface waters (algal pigments), fluorescent techniques to evaluate productivity and condition of algae; rapid bioassays for water toxicity (bioluminescence, chemotaxis techniques). Kinetic experiments:microcosms on evaluating self-purification rates; special cultivators to evaluate the rates of growth of hydrobionts and radioactive engulfing, nutrition spectra; methods of finding growth limiting factors. Models:application of Bellman Principle to optimizing the river water use; theory and peculiarities of microbiological decomposition of pollutants in the river ecosystem. The composition of Prognostication Simulation Model is the next:1) hydrodynamical unit to calculate 2-dimensional space-time rate of stream on any depth; 2) hydrophysical unit to calculate:water temperature and level of solar radiation inside the water body; 3) ecosystem unit to calculate dynamic of concentration of phytoplankton, zooplankton, bacteria, major chemical matters and pollutants in water, content pollutants inside of hydrobionfs cells and dynamic of bentos; 4) radioe-cological unit to forecast the dynamic of radionuclides in the water body and bottom, their hydro-bont''s concentration; 5) database. Reservoirs and river models are provided by monitoring and kinetic experiments data. 相似文献
4.
浮游植物对氮的吸收与其生长繁殖密切相关,太湖梅梁湾湖区蓝藻水华频频暴发,对该水域浮游植物氮吸收进行研究具有重要意义.本文分别在冬、春、夏、秋4个季节于梅梁湾采样,对水体常规理化指标和浮游植物群落结构进行分析,并利用15N稳定同位素示踪技术研究了浮游植物对铵态氮(NH4+-N)、硝态氮(NO3--N)和尿素态氮(Urea-N)吸收的动力学特征.结果表明,太湖梅梁湾浮游植物群落除了秋季对NH4+-N的吸收不符合米氏方程外,其余均符合.冬季和春季3种形态氮最大吸收速率(Vmax)的大小依次为:NH4+-N > NO3--N > Urea-N,而夏季为:NH4+-N > Urea-N > NO3--N.3种形态氮Vmax的季节变化规律为夏季 > 秋季 > 春季 > 冬季.Vmax在不同季节以及不同形态氮之间的差异性可能与浮游植物群落组成以及水体中NH4+-N浓度不同有关.浮游植物对NH4+-N吸收的KS值在冬、春季高于夏季,对Urea-N吸收的Ks值则在夏、秋季高于冬、春季,而对NO3--N吸收的Ks值则在夏季显著高于其他3个季节.冬季和春季梅梁湾浮游植物群落最容易受到NO3--N限制,而最不容易受到Urea-N的限制;而夏季,则最容易受到NO3--N限制,而最不容易受到NH4+-N的限制,且浮游植物群落对NH4+-N的亲和力最高.与NO3--N相比,秋季浮游植物更容易受到Urea-N的限制.不同季节,容易对浮游植物产生限制作用的氮的形态不同. 相似文献
5.
Lake Gucheng is located in the southeast of Nanjing, with an area of 24.3 km2, an average depth of 2 meters. The macrophytes of the lake were used to be abundant and their biomass was about 4.96 mg·m-2. The annual average contents of total phosphorus (TP), total nitrogen (TN), PO3- -P, CODMn and BOD5 0.03, 1.31, 0.005, 3.61 and 1.46 mg·L-1, respectively. Thus, the water quality of this lake is quite well. Recently, the water quality in pari of the lake became worse because of some unreasonable exploitation and utilization of bioresources. The interactions between phytoplankton (N1), macrophyte (N2), fish (N3), crab (N4) were studied here. The macrophyte has great influences on both phytoplanktons, fish and crab, controlling the water quality and maintaining the fishery productivity. On the other hand, the phytoplankton, fish and crab also influence the macrophyte. It is key method of ecological management to maintain the macrophyte by fishery culture. Therefore, a modified Lotka-Volterra model has been established to estimate the interaction between N1, N2, N3, N4 and the influences of some water environmental parameters on these aquatic organism, environmental and economic effect. The main model consists four compart-mental models and four submodels, involved 12 external variables, 8 state variables, 19 universal constants and 11 parameters. The values of most parameters were found from our experiments and calibrated by the model and actually measured data. The model has been validated by comparison the computed and experimental data of phytoplankton and macrophyte. The theoretical outputs showed a good agreement with the measured data. This model predicated that if the standing crop offish and crab was higher than 2.65 ·m-2 during springtime in this lake, macrophytes would not grow, chlorophyll a content would arrive 34.8 mg·m-3 and the water quality would decrease. If the macrophyte grow well, the maximum fishery productivity would be about 1 600 t. In this case, the annually averaged phytoplankton chlorophyll a content should be 3.69 mg·m-3, which is lower than the criterion (10 mg·m-3) for eutrophic state. From 1991 to 1996, Lake Gucheng was managed with this model, its water quality maintain quite well, chlorophyll a content decreased from 3.51 (1991) to 1.89 mg·m-3 (1994). Meanwhile, the fishery productivity increased and the economic effect heightened year by year. 相似文献
6.
湖光岩玛珥湖水体中营养盐的时空分布特征及其影响因素 总被引:1,自引:0,他引:1
湖光岩玛珥湖是世界上最大的玛珥湖,它几乎是封闭的,受外界的干扰小.目前有关玛珥湖的研究主要集中在古气候及生态环境研究方面,而有关玛珥湖营养盐在一年中的生物地球化学循环的研究较少,因此研究湖光岩玛珥湖营养盐的生物地球化学过程具有重要意义.于2015年10月-2016年9月对湖光岩玛珥湖全水柱的营养盐及其他相关参数进行逐月调查,分析营养盐的结构特征、垂直分布特征和时间变化情况,并讨论营养盐时空变化的影响因素.结果表明,湖光岩玛珥湖水中的无机氮(DIN)以铵态氮(NH4+-N)为主(>60%),其次是硝态氧(NO3--N),亚硝态氮(NO2--N)所占比利最低.湖光岩玛珥湖水中的硅酸盐(SiO32--Si)浓度较高,水体浮游植物生长受磷限制.冬季风期间,水体垂直混合较均匀,导致营养盐的垂直分布比较均匀;夏季风期间,水体层化,营养盐浓度在浅层水体较低,在深层水体较高.湖光岩玛珥湖表层水中的NO3--N、NH4+-N和SiO32--Si具有明显的时间变化规律:NO3--N浓度从10月-次年3月升高,从3-9月降低;NH4+-N浓度从10月-次年5月降低;SiO32--Si浓度从11月-次年5月降低,从5-9月持续升高.营养盐浓度的时间变化受有机质的矿化分解、水体的季节性混合、浮游植物的吸收、降雨的输入等多种因素的综合影响. 相似文献
7.
城镇化流域氮、磷污染特征及影响因素——以宁波北仑区小浃江为例 总被引:2,自引:0,他引:2
我国快速的城镇化过程造成了河流氮、磷等营养盐的污染和潜在的水体富营养化问题.对城镇流域水体氮、磷污染特征及其演变趋势的识别具有重要意义.本研究选取长三角典型城镇地区宁波市北仑区小浃江流域为研究对象,在流域内根据空间分布、土地利用类型、人类活动强度等情况布设样点,于2017年夏季和冬季采集水样,研究流域水体氮、磷污染的时空分布特征并分析其污染来源和评估其富营养化水平.结果表明:流域内铵态氮(NH4+-N)、;硝态氮(NO3--N)、亚硝态氮(NO2--N)、总氮(TN)、总磷(TP)和叶绿素a(Chl.a)浓度范围分别为0.63~3.25 mg/L、0.52~3.75 mg/L、0.02~0.22 mg/L、1.61~12.86 mg/L、0.02~0.74 mg/L和0.6~60.57 μg/L.各个采样点氮、磷分布具有较大的空间异质性和季节变化规律.富营养化综合指数EI评估结果显示,整个流域富营养化程度属于贫至中营养级.氮、磷浓度与土地类型面积占比的Spearman相关性统计表明,100 m缓冲区建设用地面积占比与NH4+-N、NO2--N、TN、溶解氧(DO)浓度具有显著相关性,湿地面积占比与DO浓度呈显著正相关.汇水区域内林地面积占比与NH4+-N、NO2--N、TP、PO43--P、COD、Chl.a浓度呈显著负相关,与DO浓度呈显著正相关.相关性分析和冗余分析表明城镇化的面源污染及可能存在的点源污染是小浃江流域氮、磷污染的主要来源.因此,在小浃江流域100 m范围内,控制建设用地的规模和污染排放是减轻流域氮、磷污染的主要途径.在汇水区域内,增加林地植被的面积对减少氮、磷污染具有重要影响. 相似文献
8.
E. E. Prepas T. P. Murphy G. Lawrence P. A. Chambers R. D. Robarts W. M. Tonn J. M. Burke S. Reedyk 《湖泊科学》1998,10(S1):25-30
Surface waters in western Canada often experience eutrophication-related problems with water quality, specifically high internal phosphorus loading rates and excessive phytoplankton and macrophyte production, that lead to water column anoxia and restricted fisheries habitat. A group of researchers from across Canada were involved for a seven-year period in cooperative programs for surface water quality management in western Canada, based at the University of Alberta. This paper summarises information on two techniques, hypolimnetic oxygenation and lime (Ca2CO3 and Ca(OH)2) application, used in western Canada (specifically, the province of Alberta) to manage eutrophication in standing waters (lakes and reservoirs). 相似文献
9.
入湖河口湿地四种植物群落类型的土壤氮素空间分布特征 总被引:1,自引:0,他引:1
对江苏省溧阳市大溪水库的洙漕河河口湿地中香蒲、水蓼、灯心草和芦苇四种植物生物量、氮含量及植物群落的土壤氮素分布特征进行研究,结果表明:四种植物地上生物量、地上组织氮含量、地下生物量、地下组织氮含量存在显著差异;土壤烧失量(LOI)、总氮(TN)、硝态氮(NO3--N)在垂直分布上表现为由表层向下减少的总体分布趋势,铵态氮(NH4+-N)浓度的剖面变化呈现先减少后增加的趋势;四种植物群落土壤氮浓度各不同,但均大于对照,以有机氮为主,说明湿地具有一定的储氮能力;不同的植物群落影响湿地氮素的分布.相关性分析显示,土壤LOI与TN、NO3--N和NH4+-N均存在极显著相关性,无机氮构成比例较小,仅为1.41%,表明土壤中的氮素主要以有机氮的形式存在;土壤氮浓度与植物生物量及组织氮含量相关性不大,说明土壤氮形态浓度不仅受到植物生长的影响,同时也可能受到植物根区环境、微生物数量与活性等的影响. 相似文献
10.
三峡大坝上下游水质时空变化特征 总被引:6,自引:2,他引:4
为探索三峡大坝上下游(坝上99.9 km、坝下63.0 km、全长162.9 km)水质时空变化特征,运用主成分分析和方差分析对2016年近坝段水质时空变化特征进行了分析.主成分分析表明,水文因子流量(Q)、气温(T)、水位(Z)和水质因子(水温(WT)、pH、电导率(EC)、溶解氧(DO)、悬浮物(SS)、高锰酸盐指数(CODMn)、硫酸盐(SO42-)、氟化物(F-)、总硬度(T-Hard)、硝态氮(NO3--N)、总氮(TN)和硒(Se))的变化主导着研究区域水质变化;各采样点主成分得分和双因素方差分析结果显示研究区域水质因子时间变化主要呈现出季节和不同水库运行时期的差异.消落期(2-5月),T-Hard、F-、SO42-和EC是影响河流水质变化的主导因子;汛期(7-8月),Q、SS、CODMn、NO3--N、TN和Se是影响河流水质变化的主导因子;T和WT主导着汛末(9月)河流水质变化,并引起了DO等理化特性的变化;高水位运行期(12月),Cl-是影响河流水质变化的主导因子.现阶段,DO、有机污染物(CODMn)、无机盐(SO42-和F-)、营养盐类(NO3--N和TN)、类金属元素(Se)和水体的矿化程度(T-Hard)的变化主导着区域水质的变化,是三峡大坝近坝段水域水质的控制因子.方差分析表明,河流的理化特性(DO、pH和SS)、营养盐组分构成(NH3-N和NO3--N)、无机盐类(EC和Cl-)、石油类有机污染物及粪大肠菌群(FC)等指标在坝上与坝下断面存在显著性差异.气温、水温、降雨、含沙量的季节性影响因素和水库调度运行模式是影响近坝段水质时间差异的主要因子;空间差异主要受城区污染排放和三峡水库调度引起的坝上和坝下水文和水动力学条件差异影响.因此控制研究区域因人类活动等造成的外源性污染,并针对不同类污染物质的季节变化特征实施合理的水库运行方式是近坝段水质提升的关键. 相似文献
11.
湖滨带芦苇恢复过程中沉积物氮赋存形态及含量变化:以巢湖为例 总被引:1,自引:0,他引:1
水生植被对于维持水生态系统结构和功能稳定性具有举足轻重的作用,而重建水生植物被认为是污染湖泊生态修复的重要手段.氮素是水生态系统重要的限制性元素之一,根着挺水植物生长发育无疑将深刻地影响着沉积物氮的迁移转化过程,但水生植物不同生长阶段对沉积物氮的需求和植物代谢强度均不同,目前对挺水植物完整生长过程中沉积物氮组分及含量变化认识仍十分不足.本研究通过为期120d的沉积物柱芯培养和水槽模拟试验,探究巢湖芦苇恢复完整生长过程中沉积物总氮(TN)、无机氮(TIN)与可转化态氮(TF-N)的变化及其关键调控因子.结果表明,芦苇完整生长过程将持续激发沉积物氮活性,沉积物TIN与TF-N含量逐渐增加,而沉积物TN和非可转化态氮(NTF-N)含量显著降低.模拟试验期间,指数型增长的芦苇生物量提高了沉积物铵态氮(NH_4~+-N)和硝态氮(NO_3~--N)含量,但亚硝态氮(NO_2~--N)含量却逐渐降低;与第0天相比,第120天沉积物离子交换态氮(IEF-N)、碳酸盐结合态氮(CF-N)、铁锰氧化态氮(IMOF-N)和有机态及硫化物结合态氮(OSF-N)含量分别增加了 1.10、3.40、3.60和1.40倍,这主要受芦苇吸收利用、根系代谢强化根际沉积物氧化还原电势和改变pH微环境共同驱动.在第120天,沉积物NH_4~+-N和NO_3~--N含量急剧升高,分别是第90天的9.43和2.22倍,表明芦苇衰亡凋落过程将向沉积物释放大量的TIN,故需要综合采取湖泊物理—生态工程手段来有效管控芦苇枯落物,从而提升水生植被修复效果并构建长效稳态机制. 相似文献
12.
The changes of NH3-N, NO3-N, NO2-N and TN/TP were studied during growth and non-growth season in 33 subtropical shallow lakes in the middle and lower reaches of the Yangtze River. There were significant positive correlations among all nutrient concentrations, and the correlations were better in growth season than in non-growth season. When TP>0.1 mgL?1, NH3-N increased sharply in non-growth season with increasing TP, and NO3-N increased in growth season but decreased in non-growth season with TP. These might be attributed to lower dissolved oxygen and low temperature in non-growth season of the hypereutrophic lakes, since nitrification is more sensitive to dissolved oxygen and temperature than antinitrification. When 0.1 mgL?1>TP>0.035 mgL?1, TN and all kinds of inorganic nitrogen were lower in growth season than in non-growth season, and phytoplankton might be the vital regulating factor. When TP<0.035 mgL?1, inorganic nitrogen concentrations were relatively low and NH3-N, NO2-N had significant correlations with phytoplankton, indicating that NH3-N and NO2-N might be limiting factors to phytoplankton. In addition, TN/TP went down with decline in TP concentration, and TN and inorganic nitrogen concentrations were obviously lower in growth season than in non-growth season, suggesting that decreasing nitrogen (especially NH3-N and NO3-N) was an important reason for the decreasing TN/TP in growth season. The ranges of TN/TP were closely related to trophic level in both growth and non-growth seasons, and it is apparent that in the eutrophic and hypertrophic state the TN/TP ratio was obviously lower in growth season than in non-growth season. The changes of the TN/TP ratio were closely correlated with trophic levels, and both declines of TN in the water column and TP release from the sediment were important factors for the decline of the TN/TP ratio in growth season. 相似文献
13.
以太湖重度蓝藻水华发生的西北湖区为研究对象,从河口至湖心区设置5个采样点,于2012年10月至2013年10月逐月采集表层水体样品,测定了水温、溶解氧和浮游细菌丰度,并分析了浮游植物群落结构的组成、溶解性无机氮(DIN)和有机氮(DON)浓度以及氮磷比.研究结果表明,太湖西北湖区浮游植物主要由蓝藻、硅藻、绿藻和隐藻组成.可能由于风、浪等混合作用使太湖西北湖区不同采样点之间蓝藻细胞密度没有显著差异.蓝藻生物量在浮游植物中所占比例最高为34%±15%,春季部分点位隐藻生物量高于50%,表明隐藻与蓝藻的相互竞争趋势显著.CCA排序图结果表明,DIN、DON浓度以及总氮∶总磷比(TN∶TP比)是影响西北湖区浮游植物优势属分布的重要环境因子.5个采样点铵态氮(NH_4~+-N)与DIN浓度具有显著差异,与DON浓度没有显著差异.夏季蓝藻水华暴发期间,可能由于蓝藻的吸收利用引起NH_4~+-N和硝态氮(NO_3~--N)浓度迅速降低.此外,由于NH_4~+-N浓度还可能受到沉积物NH_4~+-N释放的影响,因此,蓝藻细胞密度与NO_3~--N的相关系数和显著水平均高于NH_4~+-N.夏季TN∶TP比和DIN∶TP比降至最低,表明该湖区浮游植物,尤其是蓝藻的生长可能受到氮限制.蓝藻细胞密度与DON浓度呈显著负相关,表明在氮限制条件下,DON可能是蓝藻氮素利用的重要补充. 相似文献
14.
城市污染河道沉积物可提取态氮的提取方式比较 总被引:4,自引:0,他引:4
以城市污染河道——南京仙林大学城九乡河表层沉积物为研究对象,探讨沉积物常用提取剂(1 mol/L KCl、2 mol/L KCl、4 mol/L KCl和0.01 mol/L CaCl2)在不同液土比(5∶1、10∶1、50∶1和100∶1)条件下,对城市污染河道沉积物可提取态氮(NH4+-N、NO3--N)测定的影响.结果表明:KCl的提取效果要优于CaCl2,二者NH4+-N提取量分别为312.17~479.23、177.52~339.31 mg/kg,NO3--N提取量分别为4.49~21.56、4.25~8.53 mg/kg;可提取态氮提取量随液土比增高而增大,其中1 mol/L KCl组,液土比100∶1时NH4+-N和NO3--N提取量分别比液土比5∶1时增加41.97%和187.08%;NH4+-N提取量随提取剂浓度增高而增大,NO3--N随提取剂浓度增高而降低;采用1 mol/L KCl提取剂、液土比100∶1的组合联合提取城市污染河道沉积物中的NH4+-N、NO3--N,提取效果较好. 相似文献
15.
An outdoor experiment testing the effect of water flea (Daphnia longispina) and zebra mussels (Dreissena polymorpha) on physical and chemical water parameters and chlorophyll concentration changes was carried out in 12 containers filled with 150 l of unfiltered water from a lowland reservoir. During the 11 weeks of the experiment, the following physical, chemical and biological measurements were recorded: temperature (°C), oxygen concentration (mg dm−3), pH, conductivity (S cm−1), concentration of phosphate phosphorus (PO4-P) and ammonia nitrogen (NH4-N) (g dm−3), total nitrogen (TN) and total phosphorus (TP) (g dm−3), phytoplankton community structure and chlorophyll a concentration (g dm−3). The amount of ammonia ions was the highest in the treatment with zooplankton, while phosphate ions reached the highest values in treatments with zebra mussels. The results confirmed the ability of Daphnia to increase the NH4:PO4 ratio, whereas excretion from zebra mussels resulted in a decrease in both the N:P ratio (ranging from 9 to 13) and the NH4:PO4 ratio in water. In both treatments containing zebra mussels, P-rich water enabled sudden growth of Chlorophyta, resulting in blooms of Hydrodictyon reticulatum after 3–4 weeks of the experiment. Such phenomena were not observed in the control and Daphnia treatments. Our results indicate that zebra mussels, in contrast to Daphnia, may increase the symptoms of water eutrophication and contribute to blooms of expansive phytoplankton species. 相似文献
16.
基于2019年夏季(8月)对岱海水样的实测数据分析,通过运用克里金插值、相关性分析、多元线性逐步回归、主成分分析方法,探究了叶绿素a(Chl.a)的空间分布特征及其与水环境因子的相关关系,并讨论了相应的防治措施。研究显示:Chl.a空间分布呈现由岸边向湖心递减的趋势,总氮(TN)、总磷(TP)、氨氮(NH3-N)、硝态氮(NO-3-N)、正磷酸盐(PO3-4-P)空间分布特征与Chl.a空间分布特征相近,采样期内岱海湖局部区域水质状况已达到富营养状态;Chl.a与浊度(Turbidity)、TP、TN、悬浮物(SS)、pH、NO-3-N、NH3-N、PO3-4-P、蓝绿藻丰度(CYANO)呈极显著正相关,与溶解氧(DO)呈显著负相关,与电导率(Cond.)呈正相关、与氮磷比(TN/TP)呈负相关;各湖区Chl.a与环境因子相关关系不同,全湖逐步线性回归方程为YChl.a=-21.42+8.658XpH-0.865XDO+0.779XNH3-N+0.699XTurbidity+0.502XCYANO;岱海不同湖区因子对Chl.a浓度的影响存在差异,各湖区Chl.a与环境因子相关关系不同,通过岱海与我国其他湖泊Chl.a与环境因子的相关性关系对比分析,湖泊地理属性差异及营养物质输入浓度是影响Chl.a变化的重要因素;本研究岱海的TN/TP平均值为12.23,说明夏季岱海湖Chl.a变化为氮磷共同限制。 相似文献
17.
城市湖泊不同水生植被区水体温室气体溶存浓度及其影响因素 总被引:2,自引:1,他引:1
为了解城市湖泊不同水生植被区水体温室气体的溶存浓度及其影响因素,于2015年4-11月按每月2次的频率采用顶空平衡法对聊城市铃铛湖典型植被区——菹草区、莲藕区和睡莲区表层水中CO2、CH4和N2O的溶存浓度进行监测,计算水中温室气体的饱和度和排放通量,并测定水温(T)、pH、溶解氧(DO)、叶绿素a及营养盐浓度等理化指标,以探究水体环境因子对温室气体溶存浓度的影响.结果表明,铃铛湖各植被区水体温室气体均处于过饱和状态,是大气温室气体的"源";莲藕区CH4浓度、饱和度和排放通量均显著高于菹草区,而各植被区N2O和CO2均无显著性差异;不同植被区湖水中DO、总氮(TN)、总磷(TP)和硝态氮(NO3--N)浓度具有显著差异,其中DO、TN和NO3--N浓度均表现为菹草区最高,莲藕区最低,而TP浓度则正好相反;各植被区温室气体浓度和水环境参数间的相关分析和多元回归分析的结果表明,水生植物可通过影响水体的理化性质对温室气体的产生和排放产生显著差异影响,在菹草区亚硝态氮(NO2--N)、NO3--N、T和DO是控制水体温室气体浓度的主要因子;睡莲区为TP和pH;莲藕区则为pH、NO2--N和DO. 相似文献
18.
本研究在太湖梅梁湾采集沉积柱,采用一种自制的毫米级柱状沉积物自动垂向分层切割装置对表层50 mm沉积物进行垂向切割(间隔2 mm),结合高通量测序技术分析沉积物中细菌群落的毫米级垂向分布;同时采用毫米级高分辨透析技术和薄膜扩散梯度技术(DGT)分析溶解态和DGT可获取态铵态氮(NH4+-N)、硝态氮(NO3--N)、Fe、P的垂向分布特征。结果显示,沉积物中细菌群落与溶解态和DGT可获取态氮铁磷浓度在垂向上呈现显著的异质性。细菌硝酸盐还原主要发生在-16~0 mm沉积物深度,这可能导致了溶解态和DGT可获取态NO3--N含量在该沉积物深度的明显减少。细菌铁还原主要分布在-32~-18 mm沉积物深度,细菌硫酸盐还原主要分布在-50~-34 mm的沉积物深度;细菌硫酸盐还原是导致沉积物溶解态和DGT可获取态铁磷浓度从-32 mm随沉积物的深度增加而显著增加的主要原因。本研究加深了对富营养化湖泊沉积物中细菌影响氮磷在垂向上迁移转化的认识。 相似文献