基于氢氧同位素和水化学的祁连山老虎沟冰川区径流过程分析

基于2012-2013年两个消融期在祁连山老虎沟冰川区连续2 a采集的冰川融水径流、雪冰以及降水样品,分析探讨了冰川区水体介质中氢氧同位素和水化学要素(主要化学离子、pH值、TDS和电导率等)在消融期的变化过程及特征。结果表明:祁连山老虎沟雪冰融水中的氢氧同位素值(δD和δ¹⁸O)表现出明显的消融期随月份波动,先升高再降低的趋势,在7月份表现出高值,反映了冰川消融强弱程度的变化过程。冰川径流中同位素含量与冰雪融水接近,且处于当地降水线上,其主要来自冰雪融水和降雨补给。老虎沟冰川融水径流水化学主要表现为Ca-Na-HCO₃-SO₄和Ca-Mg-HCO₃-SO₄型,其组成特征也表现出随消融过程而变化。对氢氧同位素和化学要素组成在消融期(6~9月)随时间的变化过程进行了分析,表明结合冰川区氢氧同位素和化学要素(包括化学离子、TDS、pH值和电导率等)的组成可以区分雪坑和新雪、河水的组分变化,可以反映冰川融水径流在消融期的变化过程。     

青藏高原各拉丹冬冰芯记录的季节气温变化

2005 年10-11 月中美联合考察队在各拉丹冬峰北部果曲冰川平坦的粒雪盆 (33^o34'37.8"N, 91^o10'35.3"E, 5720 m a.s.l.) 钻取了一支冰芯, 通过对该冰芯进行多参数定年, 恢复了青藏高原中部各拉丹冬地区近70 年来降水中δ¹⁸O 的变化历史。根据冰芯中季风期和非季风期δ¹⁸O 值与临近气象台站气温的正相关性, 重建了该地区70 年来的春季和夏季的气温变化。结果表明, 各拉丹冬冰芯中δ¹⁸O 记录的春季和夏季升温趋势非常明显; 根据回归分析, 冰芯中非季风期的δ¹⁸O 每增大(或减小) 1‰相当于春季气温升高(或降低) 1.3 ^oC; 季风 期的δ¹⁸O 每增大(或减小) 1‰相当于夏季气温升高(或降低) 0.4 ^oC; 各拉丹冬冰芯中δ¹⁸O 记录恢复的春季和夏季气温与北半球春季和夏季的气温变化具有一致的趋势, 但各拉丹冬地区的增温幅度比北半球要大, 同时春季的增温幅度也高于夏季。     

呼图壁河流域水体氢氧稳定同位素特征及转化关系

在气候变化和人类活动影响下,水资源短缺是干旱区面临的一个严峻问题.解决问题的关键是要深入了解干旱区独特的水循环机理,而分析不同水体中氢氧同位素特征及转化关系,是应用同位素示踪技术研究水循环机理的基础。以呼图壁河流域为研究区,分析了大气降水、河水、地下水和积雪融水氢氧同位素变化特征及不同水体的δD~δ¹⁸O关系,探讨了地表水对地下水的补给关系。结果表明：呼图壁河流域大气降水、河水、地下水和积雪融水中δD、δ¹⁸O的组成和季节变化差异较大,δD值分别为-86.25‰、-66.66‰、-69.82‰和-150.79‰,而δ¹⁸O值依次为-12.42‰、-9.94‰、-10.23‰和-19.42‰;河水受大气降水和冰雪融水的混合补给导致同位素的贫化,积雪融水主要受蒸发的影响导致同位素的富集,而河水和积雪融水对地下水有密切的水力联系,导致地下水同位素的贫化;呼图壁河上游地区河水对地下水的补给仅占到18.45%,而中下游区域的地下水补给占到90%以上。     

天山山区典型内陆河流域径流组分特征分析

通过对天山南北坡的两个典型流域降水、地下水、河流、融冰雪水δD和δ¹⁸O及水化学检测,基于同位素径流分割模型定量分析了年内径流组分特征。结果表明：（1）两条河流的径流组成中地下水为构成径流的主要成分,其次是冰川融水,融雪水及降水,但南北坡径流组分表现出较明显的差异,乌鲁木齐河流域中冰川融水的比重要大于黄水沟流域,对气候变化响应明显。（2）两条河流在不同季节径流组分也表现出较大差异,春季径流组分差异最为明显。     

党河流域敦煌盆地地下水补给与演化研究

综合应用水文地球化学指标和稳定同位素技术研究了党河流域敦煌盆地地下水补给和演化规律。岩盐、石膏及芒硝等矿物的溶解对Na⁺、Ca²⁺、Cl^-及SO₄^2-离子浓度影响较大。阳离子交换作用明显,地下水中Mg²⁺和Ca²⁺浓度增加,并与碳酸盐发生沉淀,导致HCO₃^-减少。地下水的δ¹⁸O值介于-12.1‰~-7.5‰,δ²H值变化范围为-84.3‰~-61.5‰,指示了盆地不同地带地下水补给来源不同。潜水δ¹⁸O和δ²H数值随着地下水径流路径方自西南到东北越来越富集,反映了蒸发浓缩效应,南湖、盆地南部潜水同位素与河水相近,体现了现代补给。相比之下,承压水稳定同位素相对贫乏,指示过去寒冷时期的补给。该研究可以为敦煌区域地下水资源规划和管理提供一定的借鉴意义。     

长沙地区蒸发皿水体蒸发过程中稳定同位素的变化特征

蒸发过程中水体同位素分馏与蒸发时的气象要素密切相关。为此,于2013年6―9月份在长沙地区进行了4组室外蒸发皿蒸发实验,从而探讨蒸发剩余水体中稳定同位素与温度、相对湿度等气象要素之间的关系。实验结果表明：1）剩余水体中稳定同位素比率随着剩余水比例f的减少而富集,在高温无雨的伏旱天气下,蒸发剩余水体中稳定同位素分馏结果与瑞利分馏模式比较吻合;2）温度越高,分馏效应也将变大,蒸发过程中稳定同位素比率的改变量也将变大,随着水体质量的减小,稳定同位素比率的变化与相对湿度呈现负相关,尤其到蒸发后期,负相关关系更为明显,这可能是由于实验后期剩余水体绝对质量太小,易受空气中稳定同位素的影响;3）蒸发线δ2H＝3.89δ18O－24.55与δ2H＝3.38δ18O－24.96的斜率和截距明显小于同时期长沙降水线δ2H＝6.85δ18O－4.4的斜率和截距,与同时期湘江河水蒸发线δ2H＝3.9δ18O－13.2的斜率接近。以上结果说明本蒸发皿实验能一定程度上体现夏季自然水体蒸发分馏情况。     

祁连山东部大气降水分δ17O变化特征及水汽输送

祁连山作为我国西部重要生态安全屏障,是河西走廊内陆河流域核心水源区。通过测定2013年7月~2014年7月收集的降水样品中δ¹⁷O与δ¹⁷O值,分析了祁连山东部乌鞘岭大气降水中δ¹⁷O的特征,在此基础上对水汽来源进行了研究。结果表明：降水稳定同位素¹⁷O存在夏高冬低的变化特征;¹⁷O存在显著的温度效应而不存在降水量效应,¹⁷O与水汽压在干季呈现正相关关系。研究区大气降水的氧同位素降水线方程为：δ′¹⁷O = 0.509δ′¹⁷O -0.16,低于氧同位素全球降水线斜率;过量δ¹⁷O表现出夏低冬高的特点;综合分析氧同位素大气降水方程线和过量δ¹⁷O变化,发现该区域大气降水主要受局地水循环和大陆气团控制。祁连山东部地区主要受到西风和东南季风携带水汽影响,东南季风携带水汽对于祁连山东部的影响主要集中于夏季。研究可提高对祁连山区降水同位素演化的认知,为寒旱区同位素水文学的进一步研究奠定基础。     

中国典型山地温冰川水化学空间分布特征与近期冰川动态

从我国玉龙雪玉典型温水王白水１号冰川不同区段表面融水,新近积雪和冰川初给河水采样分析结果表明,雪线以下降水中的稳定同位素的离子含量比雪线以下为高,低海拔河水比高海拨融水的氧同浓度为低,可能在来源上存在着差异,这种分布特征说明本温冰川区局部大气环流情况高度而不同,有可能存在季气候区所特有的“降水量效应”或“季节性效应”。冰川不同水体内离子浓度变化说明,冰川融水与地壳表面接触时间越久,其中的可融性离了     

珠穆朗玛峰地区雪冰中重金属浓度与季节变化

对2005 年9 月采自珠穆朗玛峰北坡海拔6523 m 的东绒布冰川积累区一批雪坑样品中重金属Ba, Co, Cu, Zn 和Pb 的浓度利用电感耦合等离子体质谱仪进行了测试, 重金属浓度范围分别为(pg/ml); Ba2~227、Co2.8~15.7、Cu 10~120、Zn29~4948、Pb14~142。并利用气体稳 定同位素质谱仪MAT-252 对样品稳定氧同位素比率(δ¹⁸O) 进行了测试, 雪坑样品对应的时间为2004 年夏到2005 年秋, δ¹⁸O和重金属元素的浓度都存在着季节变化特征。在夏季风期间δ¹⁸O 值和重金属元素的浓度都很低,而在非夏季风期间δ¹⁸O值和重金属元素浓度升高,反映了不同的水汽来源对重金属浓度季节变化的影响及其环境意义。Co, Cu, Pb, Zn 的地壳富集系数(EF_c) 分别为: 3.6、27、33、180, 表明该地区Pb, Cu, Zn 已经受到了人类活动的污染, 其中Zn 受到的污染最大。     

敦煌盆地降水稳定同位素特征及水汽来源

基于敦煌盆地2012年11月至2013年11月降水氢、氧稳定同位素数据 (δD、δ¹⁸O和d-excess),结合GNIP降水同位素监测资料和HYSPLIT 4模型对降水后向气团传输路径模拟结果,对敦煌盆地降水稳定同位素特征及水汽来源进行研究。结果表明:敦煌盆地降水δD和δ¹⁸O存在明显的季节效应,即降水δD和δ¹⁸O具有夏高冬低的变化特征;同时降水δD和δ¹⁸O表现出显著的温度效应,温度每升高1 ℃,δD增加6.89‰,δ¹⁸O增加0.92‰。敦煌盆地局地大气水线(LMWL)为δD=7.45δ¹⁸O+2.72(R²=0.98),受降水二次蒸发的影响,其斜率和截距均低于全球大气水线(GMWL)。降水d-excess受当地气温和相对湿度的影响,冬半年(11月至次年4月)偏正,夏半年(5-10月)偏负。从全年来看,敦煌盆地降水水汽主要来源于西风输送,冬季和春季受极地气团的影响,夏季部分降水事件受西南季风和局地再循环水汽的影响。     

Comparisons of stable isotopic fractionation in winter and summer at Baishui Glacier No. 1, Mt. Yulong, China

Based on the data of δ18O in surface snow, snow pits, meltwater and the glacier-fed river water at Baishui Glacier No.1, Mt. Yulong, the isotopic fractionation behaviors in the typical monsoonal temperate glacier system in winter and summer were compared. The results indicate that the isotopic fractionation degree in summer is greater than that in winter, suggesting that the snow/ice melting is more intense in summer. Moreover, whenever it is in winter or summer, from surface snow to meltwater, and to glacier-fed river water, the gradient of δ18O with altitude gradually increases. This shows that the degree of isotopic fractionation gradually strengthens when surface snow is being converted into meltwater and finally into glacial river water, which suggests that the influence of post-depositional processes on δ18O gradient in the monsoonal temperate glacier region differs spatially.     

玉龙雪山冰川稳定同位素分馏冬夏对比

1 Introduction Under the dominance of South Asian monsoon, China’s temperate glaciers are distributed on Hengduan Mountains (southeast of Tibetan Plateau), the central part and southern slope of the Himalaya Mountains as well as the central and eastern p…     

Distribution features of stable oxygen isotopes in the typical monsoon temperate-glacier region, Mountain Yulong in China

During the summers of 1999 and 2000, sampling was carried out in Mt. Yulong, for the investigation of the spatial distribution of oxygen stable isotope in the atmospheric glacial hydro system and similar results obtained in the two years have confirmed our conclusion. There is an evident negative correlation between stable isotopic composition and air temperature precipitation amount, suggesting that there exits a strong "precipitation amount effect" in this typical monsoon temperate glacier region. There are marked differences between the δ 18 O values in winter accumulated snow, glacial meltwater, summer precipitation and glacier feeding stream. Under the control of varied climatic conditions, spatial and temporal variations of above glacial hydro mediums are apparent. Isotopic depletion or fractionation and ionic changes had occurred during the phase change and transformation processes of snow ice, ice meltwater, flowing of runoff and contact with bedrock. The variation of stable isotope in a runoff can reflect not only its own flowing process but also its different feeding sources.     

Glacier meltwater runoff process analysis using δD and δ<Superscript>18</Superscript>O isotope and chemistry at the remote Laohugou glacier basin in western Qilian Mountains,China

Stable hydrogen and oxygen isotope has important implication on water and moisture transportation tracing research. Based on stable hydrogen (δD) and oxygen (δ¹⁸O) isotope using a Picarro L1102-i and water chemistry (e.g. major ions, pH, EC and TDS) measurement, this study discussed the temporal variation and characteristics of stable hydrogen and oxygen isotope, chemistry (e.g. TDS, pH, EC, Ca²⁺, Mg²⁺, Na⁺ and Cl^-) in various water bodies including glacier meltwater runoff, ice and snow, and precipitation at the Laohugou glacier basin during June 2012 to September 2013. Results showed that δD and δ¹⁸O in the meltwater runoff varied obviously with the temporal change from June to September, showing firstly increasing trend and then decreasing trend, with the highest values in July with high air temperature and strong glacier melting, which could indicate the temporal change of glacier melting process and extent. Variations of δD and δ¹⁸O in the runoff were similar with that of snow and ice on the glacier, and the values were also above the GMWL, which probably implied that the glacier runoff was mainly originated from glacier melting and precipitation supply. The glacier meltwater chemical type at the Laohugou glacier basin were mainly composed by Ca-Na-HCO₃-SO₄ and Ca-Mg-HCO₃-SO₄, which also varied evidently with the glacier melting process in summer. By analyzing the temporal change of stable hydrogen and oxygen isotope and chemistry in the melting period, we find it is easy to separate the components of the snow and ice, atmospheric precipitation and melt-runoff in the river, which could reflect the change process of glacier melting during the melting period, and thus this work can contribute to the glacier runoff change study of large-scale region by stable isotope and geochemical method in future.     

Isotopic analysis of the snow cover at an alpine glacier as an indicator of local climatic variations and isotopic homogeni zation processes

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Geochemistry of groundwater in front of a warm‐based glacier in Southeast Greenland

Groundwater in front of warm‐based glaciers is likely to become a more integrated part of the future proglacial hydrological system at high latitudes due to global warming. Here, we present the first monitoring results of shallow groundwater chemistry and geochemical fingerprinting of glacier meltwater in front of a warm‐based glacier in Southeast Greenland (Mittivakkat Gletscher, 65° 41′ N, 37° 48′ W). The groundwater temperature, electrical conductivity and pressure head were monitored from August 2009 to August 2011, and water samples were collected in 2009 and analyzed for major ions and water isotopes (δD, δ¹⁸O). The 2 yrs of monitoring revealed that major outbursts of glacier water during the ablation season flushed the proglacial aquifer and determined the groundwater quality for the next 2–8 weeks until stable chemical conditions were reached again. Water isotope composition shows that isotopic fractionation occurs in both groundwater and glacier meltwater, but fractionation due to evaporation from near‐surface soil moisture prior to infiltration has the most significant effect. This study shows that groundwater in Low Arctic Greenland is likely to possess a combined geochemical and isotopic composition, which is distinguishable from other water sources in the proglacial environment. However, the shallow groundwater composition at a given time is highly dependent on major outbursts of glacier water in the previous months.     

南极普里兹湾临近海域夏季纽鳃樽对浮游植物的摄食研究

于 1 998年 1 2月至 1 999年 1月南极夏季 ,对南大洋普里兹湾临近海域主要被囊类纽鳃樽的数量密度分布进行了现场调查 ,同时于 - 3站对纽鳃樽对浮游植物的摄食率利用肠道色索法和颗粒递减法进行了现场研究。调查结果表明 ,纽鳃樽主要分布于调查海区的浮冰区北部边缘及其以北的开阔水域。在密集区其数量密度高达 2 795ind..1 0 0 0 m- 3,浮冰区几乎没有发现。 - 3站现场摄食实验结果显示 ,纽鳃樽个体肠道色素含量变化范围为 0 .1 4～ 1 .2 7μg.ind.- 1,平均为0 .98μg.ind.- 1。肠道色素法测得的纽鳃樽对浮游植物的摄食率为 7.9μg.ind.- 1d- 1,滤水率为2 81 ind.- 1d- 1。颗粒递减法测得纽鳃樽滤水率为 1 5.3± 4.61 ind.- 1d- 1,比肠道色素法所得结果偏低。虽然由此推算纽鳃樽群体的日摄食量只占浮游植物现存量的 0 .8% ,但是对于初级生产力却有一定的摄食压力 ( 72 .2 % )。     

The Characteristics and Formation of A High-Arctic Proglacial Icing

Well‐known from permafrost hydrology, icings (naled or Aufeis) are also frequently encountered at the margins of high‐latitude glaciers. The morphology of a proglacial icing at Scott Turnerbreen in the Norwegian Arctic archipelago of Svalbard is described, and the process of formation is considered in detail. Ground thermal‐regime modelling indicates an equilibrium permafrost depth of at least 200 m in the studied catchment, and it appears unlikely that groundwater contributes to icing formation. Meltwater flow through ice‐marginal drainage channels is accompanied by estimated heat fluxes of up to about 190 W m^?2, suggesting that stored meltwater may continue to percolate through thawed sub‐channel sediments when surface runoff is absent during winter. A hydraulic conductivity of 6.9 × 10^?3 m s^?1 is implied, which is consistent with other studies of glacier drainage systems. The long residence time of winter‐draining meltwater, and solute rejection by refreezing water, account for high observed concentrations of solute in interstitial water in the icing. It has often been asserted that the presence of a proglacial icing indicates that a glacier is polythermal. However, as Scott Turnerbeen is entirely non‐temperate, the presence of an icing cannot always be treated as a reliable guide to the thermal regime of a glacier.     

典型季风海洋型冰川流域水循环过程变化对气候变暖的响应(英文)

Studying the response to warming of hydrological systems in China’s temperate glacier region is essential in order to provide information required for sustainable development.The results indicated the warming climate has had an impact on the hydrological cycle.As the glacier area subject to melting has increased and the ablation season has become longer,the contribution of meltwater to annual river discharge has increased.The earlier onset of ablation at higher elevation glaciers has resulted in the period of minimum discharge occurring earlier in the year.Seasonal runoff variations are dominated by snow and glacier melt,and an increase of meltwater has resulted in changes of the annual water cycle in the Lijiang Basin and Hailuogou Basin.The increase amplitude of runoff in the downstream region of the glacial area is much stronger than that of precipitation,resulting from the prominent increase of meltwater from glacier region in two basins.Continued observations in the glacierized basins should be undertaken in order to monitor changes,to reveal the relationships between climate,glaciers,hydrology and water supplies,and to assist in maintaining sustainable regional development.