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利用2001-2002年周年太湖全湖不同湖区湖泊光学的实测资料,分析了太湖水体光学衰减系数的区域分布,季节变化,垂直分布及日变化特征,并阐述了其变化原因,将太湖与国外一些湖泊进行对比,进一步阐述了太湖的光学特征.结果表明:光学衰减系数的湖区分布大致为:河口区>五里湖>湖心区>梅梁湾>贡湖>东太湖;由于不同湖区对光学衰减系数影响的主导因素不一样,其季节变化存在差异,东太湖季节变化不大,湖心区衰减系数秋冬季较大,而梅梁湖区则夏秋较大;衰减系数日变化则表现为中午大,上午和下午小;衰减系数的垂直分布主要有逐渐递减和先递减后均匀2种类型;衰减系数的光谱特性表现为在短波部分较大,长波部分较小,670nm处有一相对高值. 相似文献
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敦煌月牙泉湖水位持续下降原因及对策分析 总被引:3,自引:0,他引:3
在分析月牙泉湖水文地质条件的基础上,依据实际调查资料和前人研究成果,定量分析了月牙泉湖水位持续下降的原因,认为地表水开采量的不断增加和水资源利用率的不断提高所引起的区域性地下水位持续下降是月牙泉湖水位下降的主要原因,超采地下水所引起的储存资源的减少是导致月牙泉湖地下水位下降的次要原因。遏止月牙泉湖水位继续下降并逐步回升的关键是增加湖区上游地下水的补给量和减少党河灌区开采量,为此提出了农业节水和引哈济党二种治理方案,但就月牙泉湖水位恢复速度和时间及取得的社会、生态及经济效益而言,引哈济党方案优先。 相似文献
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达则错位于班怒构造带的次级盆地中,湖水最深为36 m,平均深度为20.8 m。湖表水体矿化度17.27~20.27 g/L,平均为19.46 g/L,水化学类型为(CO3+HCO3)·SO4-Na型,属弱度碳酸盐型咸水湖;在垂向上,由浅及深矿化度略有增加,水化学类型不变。湖表水体铀浓度264~324μg/L,平均铀浓度为286μg/L,8 m、18 m和28 m深度铀浓度平均值分别为288μg/L、290μg/L和300μg/L。湖底沉积物铀含量为2.31~4.08μg/g,平均铀含量为3.16μg/g,略高于我国东海大陆架海底沉积物的铀含量。达则错湖水的铀元素来自于周边岩体和地层,通过河水迁移到湖泊中。在河口混合带,铀酰离子部分吸附于悬浮物上,到湖区以碳酸铀酰的形式存在于水体中,沉淀于湖底的悬浮物铀含量没有明显增加。 相似文献
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苏干湖水系属于柴达木内流水系西北端的一个独立水系, 在现状条件下, 苏干湖盆地水循环关系为大小哈尔腾河-苏干湖的"补给-蒸发"相平衡.大小苏干湖为盆地水资源的尾闾汇集区, 生态景观大部分为戈壁荒漠, 生态植被集中分布在湖外围地下水埋深小于5 m的浅埋带.在评价分析现状水均衡的基础上, 分析了盆地水循环过程, 结合氢氧同位素测试和遥感信息提取, 得出大、 小苏干湖水体的补给来源不同, 河流来水量的变化主要反映在大苏干湖水域, 对小苏干湖水体影响较小.初步建立了苏干湖盆地生态植被变化模式, 结合引哈济党工程, 分析了不同调水情景下, 大苏干湖水体面积的变化、 地下水浅埋带的变化及生态变化. 结果表明: 在大哈尔腾河调水1.0×108m3时, 不会对苏干湖水系生态状况造成明显的影响, 因而可对敦煌生态保护起到积极作用. 相似文献
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在夏季分层期间对红枫湖南、北湖湖心的水样进行分层采集,同时测定了分层水样的温度、pH、HCO3-浓度、溶解氧(DO)、叶绿素a(Chl-a)及铵根离子(NH4+)、硝酸根离子(NO3-)、磷酸根离子(PO43-)的浓度,水体中CO2的分压(pCO2)由化学平衡及亨利定律求得。研究结果表明:光合作用、有机质降解及水体热分层是影响红枫湖夏季pCO2分布的主要因素。其中,温水层CO2欠饱和是光合作用吸收CO2引起的,温跃层中pCO2的急剧增加是光合产物降解产生CO2引起的。静水层沉积物附近pCO2最高并且还有持续增加的趋势,说明沉积物中有机质降解是静水层中CO2增加的主要原因,夏季湖底水温较高加快了沉积物中有机质的降解。分层现象使pCO2在水体中的分布差别明显,并且使静水层中CO2得到积累。此外,夏季红枫湖水体中pCO2的变化与NH4+、PO43-的变化密不可分,表现为温水层中光合作用消耗NH4+、PO43-,有机质降解过程伴随NH4+、PO43-的释放。 相似文献
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针对太湖流域存在的主要水问题,在引江济太原型试验引分水控制模式分析的基础上,建立了区域水量水质模拟与调度的耦合模型。针对模型优化的复杂性,对水量水质数值模拟的格式算法、优化调度的目标函数及约束条件、模拟与优化模型的协调衔接等关键环节,提出了合理可行的处理方法。应用研究中,针对引江济太原型试验中暴露的引水分配不合理问题,研究了特定时段内望虞河引水的合理调度,并重点分析不同工况下调水对太湖水生态环境的影响。计算结果表明,所建立的模型是可行的,对区域水量水质联合模拟与调度有一定的借鉴价值。 相似文献
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太湖及其主要入湖河流沉积磷形态分布研究 总被引:57,自引:6,他引:57
选择了我国第三大浅水湖泊--太湖及其主要入湖河流进行沉积磷形态的连续提取研究.太湖湖区沉积磷中不稳态磷(LP)及铝结合态磷(Al-P)含量很低,其余形态磷为铁结合态磷(Fe-P)<钙结合态磷(Ca-P)<有机磷(Org-P).河流沉积物中有机磷的相对含量高于湖泊沉积物,绝对含量平均值约为湖泊沉积物的3.9倍,铁结合态磷的绝对含量约为湖泊沉积物的3/4,湖区沉积物Fe-P含量与水体中PO3-4-、Chla呈显著正相关关系,同时与间隙水的氧化性呈显著负相关关系.太湖各湖区沉积物的磷形态表现为空间差异较大,活性组分的差异性要大于活性较差的组分.总的来说北部湖区沉积物中Fe-P和Org-P含量高于其他湖区,这与太湖北部湖区水体高营养级和藻类爆发关系密切.湖区沉积磷的垂直分布规律较复杂,既有随深度增加的,也有随深度降低的,河流沉积物同样如此.这与太湖及河流生态条件、污染物排放以及沉积动力学条件不同有关. 相似文献
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Yanwen Qin Quan Wen Yingqun Ma Chenchen Yang Zhichao Liu 《Environmental Earth Sciences》2018,77(11):419
As a famous project in China, the water diversion from Yangtze River to Taihu Lake Project has impacts on the water quality of Taihu Lake, especially Gonghu Bay, which is the entrance of the diversion water and the drinking water source for Wuxi and Suzhou. To investigate contamination of the antibiotics in Gonghu Bay in the period of water diversion, 16 antibiotics in 14 water samples collected from Wangyu River and Gonghu Bay in China were analyzed by liquid chromatography–tandem mass spectrometry. The results indicated that the concentration of total antibiotics in Wangyu River and Gonghu Bay ranged from 1320 to 17,209 ng/L (mean: 3920?±?3841 ng/L). The average level of different antibiotics was tetracyclines (range 1082–15,310 ng/L, mean 3161?±?3479 ng/L)?>?quinolones (range 225–1325 ng/L, mean 463?±?276 ng/L)?>?sulfonamides (range n.d.–888 ng/L, mean 402?±?248 ng/L)?>?macrolides (range 12–17 ng/L, mean 14?±?2 ng/L), and levels of the detected antibiotics in Gonghu Bay were higher than that in Wangyu River, indicating that the antibiotics pollution in Gonghu Bay were much severer than Wangyu River. Ecological risk evaluation showed that in the Wangyu and Gonghu water, trimethoprim (TMP), sulfacetamide (SAAM), sulfamethoxypyridazine (SMP), and sulfamerazine (SMRZ) presented low ecological risk levels, chlortetracycline (CTC), tetracycline (TC), roxithromycin (ROM), and sulfamethoxazole (SMX) had medium level of risk, and oxytetracycline (OTC), norfloxacin (NOR), ofloxacin (OFL), ciprofloxacin (CIP), and enrofloxacin (ENR) had high level of ecological risk. The total hazard quotient of antibiotic mixtures for each sample site indicated high risk of antibiotics in Wangyu River and Gonghu Bay. In summary, the water diversion could mitigate antibiotic pollution in Gonghu Bay to a certain degree. However, the risk of antibiotics in the Wangyu River and Gonghu Bay is still high. 相似文献
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太湖东部湖湾水生植物生长区底泥氮磷污染特征 总被引:6,自引:0,他引:6
为了解太湖东部湖湾(贡湖湾、光福湾、渔洋湾)表层底泥中氮、磷的污染特征及其与水生植物生长的关系,采集了各湖湾滨岸带水生植物生长区的表层底泥,探讨了水生植物的生长与分布对表层底泥中总氮(TN)、总磷(TP)及总有机碳(TOC)等含量的影响,并对表层底泥进行营养评价.结果表明,水生植物生长密集区底泥中TN、TP、TOC的含量均显著低于水生植物零星生长区,说明水生植物的生长对太湖东部湖湾表层底泥中营养盐与有机碳含量具有较为明显的影响;相关性分析显示,表层底泥中TOC与TN含量呈显著相关性(R2=0.832 8),而与TP的相关性则较弱(R2=0.166 5),反映了TOC在湖泊底泥中的沉积可能成为湖泊氮的重要来源,而对磷的影响较小.利用有机指数与有机氮指数两种方法分别对东部各湖湾底泥进行污染评价,贡湖湾、光福湾、渔洋湾底泥有机指数平均值分别为0.142 7、0.228 6与0.208 6,均属较清洁与尚清洁水平,而各湖湾有机氮指数平均值均为Ⅲ与Ⅳ级,说明底泥已遭受了一定程度的氮污染.因此,对水生植物零星生长区表层底泥中氮含量的控制与削减有利于湖泊富营养化的预防与治理. 相似文献
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Total organic carbon (TOC), Total nitrogen (TN) and the phosphorus species concentrations of sediment cores taken from Zhushan Bay, Meiliang Bay, and East Taihu Lake regions in Taihu Lake, a large shallow lake in China, were determined. Experimental results showed a conspicuous eutrophication trend in the northern area of Taihu Lake. Inorganic P was found to be the main phosphorus form. Fe-bound P accounted for the largest proportion of Inorganic P in Meiliang Bay, an alga-type lake region. In East Taihu Lake, a macrophytic lake region, Ca-bound P was found in higher proportions than in other lake regions, with Organic P present in similarly large proportions. With respect to Taihu Lake sediment cores, the date at approximately 20 cm layer depth was roughly identified as 1950s, while upper 5 cm layers corresponded to the turn of the century. The drastic increase in phosphorus species concentration except for Ca-bound P was indicative of the large quantities of effluent discharge into Zhushan Bay owing to the increased industrial and agricultural production from the 1950s onwards. TN, Inorganic P, Organic P, and total phosphorus (TP) concentrations increased by over 2, 2.5, 2 and 2.5-fold, respectively, over the past five decades. A large proportion of Organic P accounted for TP, and high C/N ratios indicated that East Taihu Lake can be properly classified as an oligotrophic lake. 相似文献
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Meiliang Bay and Gonghu Bay, in the north of Taihu Lake, are important water sources for the city of Wuxi, and increased eutrophication now threatens the safety of drinking water. The distribution of nitrogen (N) speciation and source of N in the surface waters in the north of Taihu Lake is studied, which was an important first step in controlling N pollution. The result shows that the average concentration of ammonia (NH4 +) and nitrate (NO3 ?) of surface water in Meiliang Bay was 0.32 and 0.35 mg/L, while 0.21 and 0.74 mg/L of Gonghu Bay, in which both bays had serious nitrate pollution. The concentrations of NH4 + and NO3 ? in the surface water of the two bays had a trend of gradual decrease from north to south. The maximum concentrations of NH4 + and NO3 ? of two bays were observed near the inflowing rivers, and the maximum concentrations of NH4 + in surface water of two bays were 0.49 and 0.61, and 0.77 and 1.38 mg/L of NO3 ?. The concentration of NH4 + in the interstitial water of the two bays had a trend of gradual decrease from west to east, but NO3 ? had the opposite tendency. The maximum concentrations of NH4 + in the interstitial water of the two bays were 5.88 and 4.64, and 3.58 and 7.18 mg/L of NO3 ?. The exchangeable NH4 + content in the sediment of Meiliang Bay had a trend of gradual decrease from north to south, but Gonghu Bay showed the reverse. The exchangeable NO3 ? content in the sediment of Meiliang Bay had a trend of gradual decrease from east to west, but a decreasing trend from north to south was observed in Gonghu Bay. The maximum concentrations of exchangeable NH4 + were determined, and the values were 96.25 and 74.90 mg/kg, as well as NO3 ? with the values of 12.06 and 7.08 mg/kg. Chemical fertilizer and domestic sewage were the major sources of nitrate in surface water of Gonghu Bay, contributing 39.16 and 47.79%, respectively. Domestic sewage was the major source of nitrate in Meiliang Bay, contributing 84.79%. The denitrification process in Gonghu Bay was more apparent than in Meiliang Bay. Mixing and dilution processes had important effects on changing the concentration of nitrate transportation in the two bays. 相似文献
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Sediment and water from the Meiliang Bay of Lake Taihu were analyzed to examine the historical relation between the accumulation
of biogenic silica (BSi) and total phosphorus (TP). The results indicate that BSi accumulation in the northern part of Lake
Taihu had been controlled by diatom production and phosphorus loading since the 1950s. BSi accumulation increased with the
growing agricultural activity since the 1950s, up to a maximum level in the 1960s. After that, BSi accumulation decreased
due to the diatom dissolution till the 1980s, and then the diatom biomass decreased with BSi accumulation increased. Lake
Taihu came into an accelerated eutrophication periods since the 1990s, while BSi accumulation began to increase but the proportion
of diatom decreased. Although the onset of silica depletion cannot be confirmed in the present work, it is clear that BSi
accumulation was restrained by the input of TP. 相似文献
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水深作为重要的湖泊水文因子,对湖泊水动力过程、化学过程和生态过程具有重要的影响。通过对1993-2002年太湖水深水质实测资料的回归分析,建立了太湖7个分区的水深与总氮、总磷、叶绿素a浓度的回归方程。结果表明,叶绿素a浓度对水深变化的响应并不显著。一般情况下,水深变化对营养盐浓度的影响不显著,但在特定的湖区,如梅梁湾,水深变化对营养盐浓度的影响显著。鉴于水深变化可以对太湖局部区域的水环境具有显著的影响,因此存在通过太湖流域水利工程的联合运行,人为调控特定湖区水深,在一定程度上改善水质的可能性。 相似文献
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Detection of algal bloom and factors influencing its formation in Taihu Lake from 2000 to 2011 by MODIS 总被引:1,自引:0,他引:1
Changchun Huang Yunmei Li Hao Yang Deyong Sun Zhaoyuan Yu Zhuo Zhang Xia Chen Liangjiang Xu 《Environmental Earth Sciences》2014,71(8):3705-3714
Time-series MODIS data were used to extract and characterize algal blooms from the Taihu Lake study area. Water quality data including total nitrogen, total phosphorus, and dissolved oxygen; local meteorology data; and global climate trends were examined to reveal the factors influencing the formation of the algal blooms. Results for the 2000–2011 study period show that the annual algal bloom typically begins between March and May in Taihu Lake. All large-scale blooms originate from northern Taihu Lake (Meiliang Bay and Zhushan Bay). Some small-scale blooms originate from southwestern Taihu Lake, but the duration of these blooms is very brief because of episodes of turbulent mixing due to high wind speed. Nutrient supply is the main factor influencing algal mass propagation during bloom periods, and temperature changes may trigger algal recovery. The algal bloom area significantly decreased when wind speed is greater than 4 m/s, causing turbulence and changes in algal buoyancy. A strong East Asian summer monsoon transporting warm air to the lake is shown to extend the duration of algal blooms in Taihu Lake, as occurred in 2007. 相似文献