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1.
本文是对横断山地区17个湖泊水体中溶解氧含迸的测定。其平均含货在5.86~8.35mg/L之间,最大含里可达14.54mg/L。湖泊中溶解氧含量在地域分布上随箝海拔高度升高而下降。由于受湖泊中水体运动影响,湖泊表层水中溶解氧分布较一致,但在深水湖泊中表层和底层含量即有明显差异,且随着水深加大溶解氧下降,如马湖,在水深l00m以下为无氧区,致使生物大量死亡。在深水层的温跃层附近(10—50m)溶解氧出现跃变现象。此外,湖泊中水生生物分布,以及有机质污染,对水体中溶解氧含量和分布亦有直接影响。 相似文献
2.
西藏当惹雍错和扎日南木错现代湖泊基本特征 总被引:5,自引:4,他引:1
湖泊现代特征的调查和对比研究是湖泊学和古湖泊学研究工作的基础,青藏高原大部分湖泊目前仍缺少详细的基本特征考察资料.基于2009年9月实地考察,本文报道藏北高原腹地的两个内陆封闭大湖——扎日南木错和当惹雍错的水深分布和现代湖水基本特征.测深结果显示扎日南木错大部分湖区水下地形较为平坦,最大水深为71.55m;当惹雍错实测最大水深为214.48m,是青藏高原上已知最深的湖泊,也是我国已知的第二深水湖.湖水理化性质显示在垂直方向上两湖都呈现明显的分层结构,温跃层的温度梯度分别为1.1℃/m和0.57℃/m,当惹雍错底层水温最低仅为1.6℃;两湖表水层的电导率分别高达18500μS/cm和12900μS/cm;两湖表水层pH都超过10,而底层水的pH都降低到5左右,上下层湖水显示了不同的酸碱性质.湖水电导率和溶解氧在温跃层都具有同步跃变特征,反映了温度对湖水性质的影响. 相似文献
3.
东太湖水温变化与水-沉积物界面热通量初探 总被引:1,自引:0,他引:1
水温对沉水植被的生长和分布具有重要作用,水-沉积物界面热通量对浅水湖泊水温变化的影响值得关注.东太湖是我国东部典型的草型浅水湖区,采用自2013年11月至2015年10月对东太湖湖心进行的不同深度水体及沉积物温度高频观测数据,结合东太湖表层沉积物的热力学性质计算了水-沉积物界面热通量,分析了东太湖水温和水-沉积物界面热通量的变化特征并探讨了其影响因素.结果表明:东太湖各深度水体日升温过程随水深增加后延,升温过程夏季延长,冬季缩短;表层水温日变幅最大,底层水温日变幅次之,沉积物温度日变幅最小,各深度温度日变幅夏季最小、冬季最大;春季和夏季升温过程中各深度日均温变化沿水深存在约1天的延迟,秋季和冬季无此现象;2015年与2014年东太湖温度变化趋势相同,同比月均温差与气温差呈线性相关.沉积物8:00-19:00向水体放热增加或从水体吸热减少,19:00至次日8:00放热减少或吸热增加;3-9月从水体吸热,为热汇,10月至次年2月向水体放热,为热源,沉积物全年为湖泊热源;逐日水-沉积物界面热通量每月6至15日存在相对年变幅较小幅度的正弦式波动.水温和水-沉积物界面热通量的变化主要受太阳辐射和气温的影响,二者对气象参数的响应具有迟滞现象;水-沉积物界面热通量与水温呈负相关,其变化相对水温迟滞,水-沉积物界面热交换的主要作用为缓冲湖泊水体的热量变化;夏季,沉水植物能降低湖泊各层水温和垂向水温差. 相似文献
4.
为探明中国北方浅水湖泊乌梁素海冰封期水体溶解氧平衡的内在机理,于2021年1—2月在湖心处布设了一台水质在线监测浮标,收集到包括溶解氧等在内的水质数据. 通过对溶解氧数据的小波降噪处理,结合气象资料,模拟分析了冰生长及稳定期内水体溶解氧的变化趋势,定性分析了水体溶解氧的平衡机理. 结果表明:湖泊的日均最高产氧速率为7.19 mg/(L ·d),最低产氧速率为2.01 mg/(L ·d); 日均最高耗氧速率为7.13 mg/(L ·d),最低耗氧速率为2.37 mg/(L ·d). 24 h的单位时间平均最高产氧速率为0.55 mg/(L ·h),最低产氧速率为0 mg/(L ·h); 单位时间平均最高耗氧速率为0.36 mg/(L ·h),最低耗氧速率为0.08 mg/(L ·h). 由此说明小时间尺度下溶解氧的补充消耗不均衡导致了大时间尺度下的溶解氧不平衡,进而产生了冬季湖泊的亏氧现象. 通过进一步溶解氧驱动因素与水环境因子响应关系的分析发现,浊度、水温与产氧速率呈显著负相关,叶绿素a与产氧速率和耗氧速率均呈显著正相关,表明了这些限制性水环境因子在一定程度上影响了冰下水体的溶解氧平衡. 相似文献
5.
西藏纳木错水深分布及现代湖沼学特征初步分析 总被引:7,自引:4,他引:3
2005-2007年对两藏最大的湖泊--纳木错进行了三次综合考察,获得了大量的基础数据和研究材料.本文简要报道纳木错水深测量及其现代湖沼学特征的初步结果.等深线图显示纳木错是一个高海拔的深水湖,湖盆中部是一个水深超过90m底部较为平坦的盆地.考察中发现湖泊西北部出现了两个小岛,而1970s考察时仍为半岛,因而水深数据提供了近30年来纳木错湖面上升的有力证据.现场水质测量在16个站点进行,覆盖了除东部湖区以外的大部分湖面范围,结果显示表层水的温度、pH、溶解氧、电导率和环境光的平均值分别为11.63℃、9.13、7.93mg/L、1839μS/cm、2582μmol/(s·m2),根据湖水特征的垂直变化,较深水域的湖水显示了明显的分层特征:上层湖水从表层到约18-20m,水质参数均一,温度较高,光照充足:中间层范围约为20-60m,是一个明显的温跃层;底层水性质也很稳定,水温很低几乎没有光线到达,形成了寒冷黑暗的深水区. 相似文献
6.
新安江水库(千岛湖)湖泊区夏季热分层期间垂向理化及浮游植物特征 总被引:20,自引:8,他引:12
2010年7月对亚热带特大型水库——新安江水库湖泊区水体的垂向物理、化学参数以及浮游植物群落进行了观测研究,并应用Water-PAM对水体浮游植物垂向光合作用参数进行了测定.研究结果表明:夏季该水库湖泊区在水下10~20 m处形成明显的温跃层,垂向pH值、溶解氧及浊度的变化同叶绿素a浓度呈现高度一致;夏季浮游植物群落以硅藻占绝对优势,水体表层以梅尼小环藻(Cyclotella meneghiniana)为主,表层以下其它各层均以巴豆叶脆杆藻(Fragilaria cro-tonensis)为绝对优势种,垂向分布表现为5~10 m区间为浮游植物高密度区域,温跃层以下浮游植物密度显著下降,水温分层可能是决定浮游植物垂向分布的重要因素之一.浮游植物最大光合效率从表层向下层逐步降低,实际光合效率最大值出现在垂向10 m区域. 相似文献
7.
2006-2015年内蒙古呼伦湖富营养化趋势及分析 总被引:4,自引:1,他引:3
以内蒙古呼伦湖为研究对象,20062015年水质数据为基础,分析呼伦湖的富营养化变化趋势及其影响因素.结果表明,20062015年呼伦湖各水质指标都有不同程度的变幅,其中盐度变化范围为0.75~1.71 ng/L,均值为1.32 ng/L,2010年达到峰值1.71 ng/L,随后呈现逐年递减趋势;pH的变化范围为8.78~9.40,水体偏碱性;透明度的变化范围为0.17~0.26 m,近三年来透明度持续下降;溶解氧浓度变化范围为4.05~10.62 mg/L,均值为7.12 mg/L.总氮浓度的变化范围为1.16~3.53 mg/L,总磷浓度的变化范围为0.13~0.25 mg/L,叶绿素a浓度的变化范围为3.31~10.36 mg/m3,N/P比变化范围为4.92~15.35,水质已经达到地表水环境质量Ⅳ~Ⅴ类水体标准,是磷限制性湖泊.利用综合营养状态指数法对呼伦湖水体富营养化进行评价,2006-2015年呼伦湖水体表现出中度—重度—中度—轻度的变化趋势.通过分析呼伦湖富营养化的影响因素,结果表明,影响呼伦湖富营养化的可能因素为外源输入和入湖径流量,同时水深和水温也是呼伦湖发生富营养化的驱动因素,pH、透明度和溶解氧是呼伦湖富营养化影响水质的最主要表现指标. 相似文献
8.
西南峡谷型水库的季节性分层与水质的突发性恶化 总被引:40,自引:3,他引:37
选择西南云贵高原乌江流域的百花湖水库进行了气象、水温度和水化学(DO、FeⅡ和MnⅡ)的连续监测(13个月).结果表明,由于气候等原因,百花湖水库的水体在夏季形成分层,但是没有典型分层湖泊的温跃层变化,这种水体温度结构可以在4-10月保持稳定;这种"不显著的"温度分层结构,有效限制了上下水团的混合,形成显著的水体溶解氧分层,氧化/还原界面可达到水深8m左右.20世纪90年代初以来,贵州多座水库频繁出现的季节性水质恶化现象,与水库水体混合期(多为夏末初秋),水体分层结构失稳有关.上下层水体的垂直交替,使下层水体中的还原性物质带入上层湖水,造成表层水体缺氧和表观浑浊,鱼类窒息死亡.在百花湖水库的研究表明,西南地区深水水库,可以在夏季出现一定的水体温度分层结构,并导致显著的水体水化学(如溶解氧)分层,进而影响水库水环境质量. 相似文献
9.
新安江水库(千岛湖)热力学状况及热力分层研究 总被引:6,自引:3,他引:3
利用2012年1-12月在新安江水库(千岛湖)6个点位的每月一次的水温及其他环境因子的周年观测资料,分析了水库水温逐月变化、季节变化、垂直分布及温跃层的形成与变化,探讨了温跃层特征量(温跃层深度、厚度、强度)与表层水温、水体透明度的关系.新安江水库表层和中层水温与气温存在显著的线性相关,又以表层水温线性关系最好,而下层水温与气温没有显著相关性,说明下层水温受气温的影响很小,全年处于相对恒温状态.水库表层和中层水温逐月变化明显,呈现夏季最高、春秋季次之、冬季最低的变化趋势,其中中层水温最高值出现的季节较表层水温明显后延,下层水温没有明显的逐月变化和季节变化.水温垂直分布显示,4个季节均存在不同程度的温跃层和温度分层现象,其中水深最深的大坝前水温分层最明显.小金山、三潭岛和大坝前3个典型点位从春季的4月份到冬季的2月份温跃层深度由1.61±0.47 m逐渐增加至39.37±5.35 m,而温跃层厚度和强度则在夏季最高、冬季最低,温跃层随着季节的变化呈现增强稳定减弱消失的周期变化.温跃层深度与水体透明度存在显著正相关,与表层水温存在显著负相关,并基于透明度和表层水温建立温跃层深度的多元线性回归模型. 相似文献
10.
高原深水湖泊水温日成层对溶解氧、酸碱度、总磷浓度和藻类密度的影响:以云南阳宗海为例 总被引:6,自引:3,他引:3
弄清深水湖泊夏季水温分层及其对水体各理化指标的影响对于湖泊的保护和治理有重要意义.以云南阳宗海为例,在夏季选择湖泊内有代表性的6个样点,以1 m为间隔对每个样点不同水深的水温、藻蓝蛋白、DO、pH和叶绿素a含量进行同步测定,同时在实验室测定TP.结果表明:(1)夏季晴天阳宗海上午没有明显的分层,中午开始慢慢形成4层,随后转化到3层,在14:00时达到分层相对稳定,稳定时温跃层出现在水深9~13 m处,湖表层与深水层的最大温差为7.8℃;(2)随着水温出现分层,DO和pH呈现出与水温分层相似的垂直分层结构,而这种分层过程基本上与水温成层过程同步;(3)藻类和浮游植物随水温分层而逐渐成层,但有迟滞性,迟滞时间约2 h;(4)TP对水温分层不敏感,只有接近湖底的水体总磷浓度才明显升高,9 m以上的水层总磷浓度分布均匀,水温的分层与消失过程不影响上层水的总磷浓度,全湖泊的总磷平均浓度为0.033±0.03 mg/L. 相似文献
11.
全球变化下青藏高原湖泊在地表水循环中的作用 总被引:2,自引:2,他引:0
青藏高原是地球上最重要的高海拔地区之一,对全球变化具有敏感响应.青藏高原作为"亚洲水塔",其地表水资源及其变化对高原本身及周边地区的经济社会发展具有重要的影响.然而,在气候变暖的情况下,构成高原地表水资源的各个组分,如冰川、湖泊、河流、降水等水体的相变及其转化却鲜为人知.湖泊是青藏高原地表水体相变和水循环的关键环节.湖泊面积、水位和水量对西风和印度季风的降水变化非常敏感,但湖泊面积和水量变化在不同区域和时段的响应也不尽相同.湖泊水温对气候变暖具有明显响应,湖泊水温和水下温跃层深度的变化能够对水—气的热量交换具有明显影响,从而影响了区域蒸发和降水等水循环过程.由于湖泊水量增加,高原中部色林错地区湖泊盐度自1970s以来普遍下降.根据60多个湖泊实地监测建立的遥感反演模型研究发现,2000—2019年湖泊透明度普遍升高.对不同补给类型的大湖水量平衡监测发现,影响湖泊变化的气象和水文要素具有较大差异.在目前的暖湿气候条件下,青藏高原的湖泊将会持续扩张.为了深入认识湖泊变化在青藏高原区域水循环和气候变化中的作用,需要全面了解湖泊水量赋存及连续的时间序列变化,需要深入了解湖泊理化参数变化及对湖泊大气之间热量交换的影响,需要更多来自大湖流域的综合连续观测数据. 相似文献
12.
Quantitative comparison of river inflows to a rapidly expanding lake in central Tibetan Plateau 
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下载免费PDF全文 The recent rapid expansion of inland lakes on the Tibetan Plateau (TP) are a good indicator of the consequences of climate change. Quantifying the hydrological cycle of the lake basin is fundamentally important to understand the causes of lake growth. However, the hydrological processes of the TP interior are very complex and difficult to investigate because of the lack of observations. This is especially true for estimating the lake changes when run‐off inflows are affected by small lakes located in the flow routes within drainage areas. We used an integrated hydrological model, in combination with glacier melt and lake retention models, to analyse the run‐off inflows to Lake Siling Co, the largest endorheic lake in Tibet. It includes four subdrainage basins: Zhajiazangbu, Zhagenzangbu, Alizangbu, and Boquzangbu. Lake Siling Co was characterized by considerable increases during warm season from 1981 to 2012, due to the increased run‐off from Zhajiazangbu accounting for about 51–62% of the total run‐off inflows. Moreover, the dramatic increases exhibited during cold seasons were related to the increased retention water released from the small lakes within Zhagenzangbu and Alizangbu. Of the studied subdrainage basins, Boquzangbu contributed the least during both warm and cold seasons. On average, the annual amount of evaporation from lakes within the drainage area was about 2 times greater than that of glacier melt run‐off. Our results suggest that the retention effects of lakes on river inflows should receive more attention, because understanding these effects is potentially crucial to improved understanding of lake variations in the TP. 相似文献
13.
湖泊热力结构不仅影响湖泊内部生态环境,而且与区域气象和气候系统相互影响,但目前对湖泊垂直温度的观测研究仍非常匮乏.本研究基于青藏高原拉昂错连续的湖温和气象观测,分析了小时尺度和日尺度热力分层规律和混合层深度的变化特征.结果表明:拉昂错为冷多次完全混合型湖泊;湖表温度8月达到最大值,湖面敞水区和沿岸的湖表温度季节震荡相同,但存在一定的空间差异;与空气温度相比,湖表温度变幅小,降温更慢,峰值滞后约1个月.同时发现,拉昂错混合层深度变化较为规律,辐射和风速是影响湖泊混合层深度的主要外界因子.探明真实的高原湖泊分层规律,有利于提高湖泊模拟能力,为优化湖泊参数化方案提供参考. 相似文献
14.
Ziqiang Xing Huojian Huang Yuanyuan Li Shanshan Liu Ding Wang Yong Yuan Zhongnan Zhao Lisheng Bu 《水文研究》2021,35(5):e14192
Hydrologic regime plays an important role in maintaining aquatic ecosystem structures and biogeochemical processes of endorheic salt lakes. Due to joint influences of regional climate change, runoff regulation and water withdrawal, ecological water deficiency has been increasingly prominent in endorheic salt lakes in Northwest China, especially in the Inner Mongolian Plateau. Previous studies mainly focused on establishing and applying methods to determine ecological water levels of lakes, while much less attention was paid to a more important problem – how such water levels could be reached under changed watershed hydrological processes. Solutions of this gap were explored in this study using the Dalinuoer Lake as an example. This lake is a typical endorheic salt lake located in the Inner Mongolian Plateau. It is a critical source to provide important ecological services and economic values for locals. Its ecological water level to maintain the optimum salinity threshold was first calculated by applying a statistical analysis of relationships between the phytoplankton biomass, salinity and water level of the lake. Potential measures to preserve the ecological water level of the lake were subsequently evaluated based on a hydrological process analysis of the watershed. The results indicated that the optimum salinity threshold was 5.7 g/L. This value should be also valid for other endorheic salt lakes in this region. According to a function between the water storage and the mean water depth of this lake, the ecological water level was determined to be 10.28 m with an ecological water deficit of 2.5 × 108 m3. A basin water balance analysis using the results proposed measures to maintain a sustainable ecological water level, including controlling local water consumption and infusing ecological water. The results of this study could be extrapolated to other similar conditions to provide guidance for policy-makers, so that better decisions could be hopefully forged to protect eco-hydrological processes of endorheic salt lakes in the Mongolian Plateau, as well as other comparable scenarios. 相似文献
15.
Differences and cause analysis of changes in lakes of different supply types in the north‐western Tibetan Plateau 下载免费PDF全文
下载免费PDF全文 Most lakes of the Tibetan Plateau were experiencing quick expansion in recent decades; a detailed study on the changes in lakes of different supply types will help to understand the cause of the changes by analysing area change of 34 lakes and water level change of eight lakes in the north‐western Tibetan Plateau. All lakes are classified into three types: non‐glacier‐fed lakes, upstream lakes and glacier‐fed lakes. The glacier‐fed lakes are separated into glacier‐fed_P1 (quick expansion region) and glacier‐fed_P2 (slow expansion region). Combining the changes in precipitation, temperature and evaporation, less precipitation may be the main reason for lake shrinkage from 1976 to 1996 and quickly increasing precipitation led to the lakes' expansion from 1996 to 2000. However, after 2000, upstream lakes remained in a stable state with slight variation, non‐glacier‐fed lakes and glacier‐fed_P2 lakes exhibited a slightly increasing rate with high precipitation and high evaporation, and glacier‐fed_P1 lakes still expanded quickly. On the basis of the assumption of same precipitation and evaporation, glacial meltwater may make an important contribution (>52%) to the increase in water storage of Bangdag Co and Meima Co. The results suggest that glacial meltwater augments the increased rate of glacier‐fed_P2 lakes and plays a much more important role in the expansion of glacier‐fed_P1 lakes compared to other lakes. 相似文献
16.
Diatom assemblages and quantitative reconstruction for paleosalinity from a sediment core of Chencuo Lake,southern Tibet 总被引:3,自引:0,他引:3
Changing salinity in lakes and especially in closed lakes depends mainly on the balance between precipitation, runoff and evaporation in arid and semi-arid areas, hence influencing lake levels di-rectly[1-4]. Past salinity has been recovered by a vari-ety of environmental indicators from lake sediments such as diatoms, chironomids, ostracoda, isotopes of ostracoda shells, geochemistry, and isotopes of authi-cabonates[3,5—10]. Recently, with extensive data-base study on diatom-salinity transfe… 相似文献
17.
Lide Tian Zhongfang Liu Tongliang Gong Changliang Yin Wusheng Yu Tandong Yao 《水文研究》2008,22(17):3386-3392
The use of stable isotopes is a practical tool in the study of the lake water budget. This is an one way to study the hydrological cycle in the large numbers of inland lakes on the Tibetan Plateau, in which the isotope record of the sediment is believed to reflect the climatic and environmental changes. The monitoring of stable isotopes of the precipitation, river and lake waters during 2004 in the inland Yamdruk‐tso basin, southern Tibetan Plateau, reveals the lake water δ18O is over 10‰ higher than the local precipitation. This high difference indicates strong isotope enrichment due to lake water evaporation. The simulation results based on the isotope technique show that the present lake water δ18O level corresponds to an average relative humidity of around 54–58% during evaporation, which is very close to the instrumental observation. The simulation results also show that the inland lakes on the Tibetan Plateau have a strong adjustability to the isotope shift of input water δ18O. On average, the isotope component in the inland lake water is to a large extent controlled by the local relative humidity, and can also be impacted by a shift of the local precipitation isotope component. This is probably responsible for the large consistence in the isotope component in the extensive inland lakes on the Tibetan Plateau. Copyright © 2008 John Wiley & Sons, Ltd. 相似文献
18.
湖泊中溶解氧极大值之成因 总被引:1,自引:0,他引:1
本文对位于台湾南部两个次高海拔湖泊-大鬼湖及万山神池进行研究,并试图探讨此二无明显进,出水口之封闭型湖泊中,水体溶解氧垂直分布出现极大值之成因,此二次高海拔湖泊地处偏远,人烟罕至,因此较不受人为干扰,为研究湖泊水体中种种自然作用的良好对象,大鬼湖平均水深约14.8m,最深处约40m,降冬季外,水体均有分层现象,1988年夏季资料显示,水深16m以下水体趋于无氧状态,且于此深度以上的溶氧饱和值,均接近当地的大气饱和值(约78%),经各种资料推断,此极大值的成因,除水团乃于春季时留下主溶氧值之外,应综合了季节增温效应下使表水向下温合的物理作用(尤其是山区明显的口,夜温差所引起的表水冷却向下混合作用,且其混合深度随季节增温而逐步变浅),消耗溶解氧的生物作用及跃层存在等影响因素,而非单纯的物理或生物作用所造成,1991年4月万山神池观测资料显示,湖水平均深度约8m,最深可达14m ,其氧饱和程序分布在80%-104%之间,表水接近近当地饱和值(78%),而于1.5m处往下增加,于2m处有溶解氧及和程度极大值,比当时大气饱合值高约20%,此极大值深度与叶绿素a极大值深度相吻合,主要由生物之光合作用造成,此外,于此深度pH值亦有明显增加现象,更证实了生物作用的存在,此二湖环境背景相似,且水泥中均出现溶氧极大值,但二者间极大值却有不同的成因,经曲两不同成因的比较,将可提供许多相关研究资料。 相似文献