天山乌鲁木齐河源1号冰川的气候敏感性研究

依据山地冰川规模对于气候变化平衡态响应的一种统计模型,探讨了天山乌鲁木齐河源１号冰川东,西支在不同气候情景下的平衡态规模大小,根据该冰川的历史变化并应用这一统计模型,对于乌鲁木齐河源地区气候变化的趋势进行了研究。     

天山乌鲁木齐河源1号冰川冰芯记录形成过程及年代划分

冰川冰芯记录了历史时期的气候环境信息.天山乌鲁木齐河源1号冰川位于亚洲大陆干旱半干旱地区的腹地,1991 -1998年在1号冰川钻取的4根深冰芯(To ～T3),用于探究该地区历史时期各项气候环境信息记录.通过化学离子季节变化特征以及δ18O和Mg2+的剖面与树轮重建的温度记录对比,分别对冰芯T2(80.1 m)的32...     

天山乌鲁木齐河源1号冰川大气气溶胶和新雪中可溶性离子关系研究

在2007年4月、8月和10月三个时段内,分昼夜采集了23个气溶胶样品和7个新降雪样品,对样品中的可溶性离子进行了分析。结果表明,乌鲁木齐河源1号冰川(以下简称1号冰川)春、夏、秋三个季节气溶胶平均载量为86.22 neq/m³,分析显示1号冰川存在NH₄HSO₄和(NH₄)₂SO₄气溶胶,并有少量NH₄NO₃气溶胶存在。气溶胶和新雪样品中可溶性离子成分变化趋势相似,气溶胶浓度升高,新雪样品的浓度也会有所升高,反之亦然。气溶胶和新雪中Ca²⁺、Mg²⁺、Na⁺、Cl^-、K⁺的相关性很好,说明雪中这些离子的浓度基本能反映大气中的状况;对气相和颗粒相并存的NH₄⁺和NO₃^-来说,雪中的离子浓度和大气中的离子浓度不相关。     

天山1号冰川旅游资源可持续利用初探

文章在分析1号冰川旅游资源禀赋，客源市场特征和发展旅游业优，劣势的基础上，着重考虑旅游基础设施建设，旅游活动以及其它生产，生活行为可能对冰川地的自然环境，生态环境，景观美学质量等产生的负面效应，并进行相应的旅游环境影响评价，由此提出1号冰川旅游资源可持续利用策略。     

东南极内陆地区和乌鲁木齐河源1号冰川表层雪内NO^—3沉积后过程差异

酸性气体成分（如ＮＯ－３）的强挥发性导致其在雪面沉降后,具有沉积后气／雪交换作用,即其在表层雪内是“可逆”沉降的。通过比较东南极内陆雪坑的ＮＯ－３剖面和乌鲁木齐河源１号冰川表层雪内ＮＯ－３的浓度变化,认为沉积后气／雪交换作用在东南极内陆较显著,而在乌鲁木齐河源１号冰川则不然。表层雪内ＮＯ－３存在方式的不同和沉降机制的差异应是导致两地ＮＯ－３沉积后过程差异的原因所在。     

乌鲁木齐河源1号冰川2009年出现物质正平衡

自1997年以来,乌鲁木齐河源1号冰川消融极为强烈,物质平衡呈大幅度亏损,连续12 a都处于强负平衡状态,平均物质平衡达-708 mm,且在2008年物质平衡达到历史最低值-999 mm,然而2009年出现了物质正平衡,物质平衡63 mm,年际变化量达1 062 mm。以2008-2009年物质平衡实测资料为基础,根据该地区的气温和降水资料分析,结果表明,造成这种现象的主要原因是夏季气温（5～8月）的降低,较2008年低1.8℃,致使冰川消融期的开始时间推迟至了7月份,结束时间提前到8月份,大大削弱了冰川的消融强度,其次是2005年以来逐渐增多的连续性降水,增加了冰川的积累量。     

天山乌一号冰川物质平衡特征的统计分析

利用天山乌鲁木齐河源一号冰川物质平衡的多年观测资料,通过数学统计方法提取主成分,获得影响该冰川物质平衡的主要因素,通过成分矩阵的旋转获得表示冰川物质平衡特征的两个主因子,其中第一主因子为影响冰川物质平衡的常年因子,代表该冰川的多年持续变化方向与趋势,第二主因子为影响冰川物质平衡的年际因子,代表该冰川在平衡年内的物质平衡变化特征。常年因子的持续下降反映了冰川持续后退的现实,年际因子在上世纪80年代中期以后突然强劲上升,实际上是冰川物质平衡水平提高,平衡年内积累量和消融量都增加的表现,清晰地指示了西北地区气候由暖干向暖湿的转型。常年因子是冰川物质平衡变化的主导因子,控制了冰川变化的方向。常年因子具有较好的周期性,以6年周期最为明显,但其形成原因尚不明。年际因子周期性不明显,但可以看出其周期与太阳黑子变化具有相关性,同时受到常年因子的影响。     

将天山一号冰川建成自然保护小区

2007年1月,《关于建立一号冰川自然保护小区的建议》成为乌鲁木齐政协十届五次会议的一号提案,正式列入大会提案目录。中国科学院新疆分院的专家们和本项提案的撰写人、政协委员阿孜古丽此前曾一起进行一号冰川的调研,为本次提案的撰写奠定了基础。     

天山乌鲁木齐河源区大西沟表土花粉散布特征

在天山乌鲁木齐河源区大西沟垂直植被带表土孢粉分析及植被调查的基础上，对大西沟垂直带的植被与表土孢粉的关系进行了探讨。从表土孢粉百分比含量可划分出4个孢粉带，其对应的植被带分别为高山垫状植被、高山草甸、亚高山草甸和云杉(Picea)林带。孢粉百分含量基本上反映了大西沟地区垂直植被带分布的特征。云杉、麻黄(Ephedra)、藜科(Chenopodiaceae)和蒿属(Artemisia)等植物花粉明显表现为超代表性。山谷上升气流在天山山地垂直植被带的表土孢粉散布中起着重要的作用。     

冰川及其径流对气候变化响应过程的模拟模型——以乌鲁木齐河源1号冰川为例

用冰川动力模型对乌鲁木齐河源１号冰川东支进行模拟计算结果表明：１号冰川东支在维持目前的气候变化水平下还将继续退缩到约１６００ｍ长度；若气温升高１℃，１号冰川将退缩为约只有３００ｍ长的悬冰川。随着冰川退缩，冰川冷却作用减弱，冰川区的升温将高于非冰川区。１号冰川目前的冰川径流是处在一个高值期（相对于它的稳定状态），若气候继续变暖，冰川径流还将继续增大，达到一峰值后将迅速减小。     

60-year changes and mechanisms of Urumqi Glacier No. 1 in the eastern Tianshan of China,Central Asia

Worldwide examination of glacier change is based on detailed observations from only a small number of glaciers. The ground-based detailed individual glacier monitoring is of strong need and extremely important in both regional and global scales. A long-term integrated multi-level monitoring has been carried out on Urumqi Glacier No. 1 (UG1) at the headwaters of the Urumqi River in the eastern Tianshan Mountains of Central Asia since 1959 by the Tianshan Glaciological Station, Chinese Acamedey of Sciences (CAS), and the glaciological datasets promise to be the best in China. The boundaries of all glacier zones moved up, resulting in a shrunk accumulation area. The stratigraphy features of the snowpack on the glacier were found to be significantly altered by climate warming. Mass balances of UG1 show accelerated mass loss since 1960, which were attributed to three mechanisms. The glacier has been contracting at an accelerated rate since 1962, resulting in a total reduction of 0.37 km² or 19.3% from 1962 to 2018. Glacier runoff measured at the UG1 hydrometeorological station demonstrates a significant increase from 1959 to 2018 with a large interannual fluctuation, which is inversely correlated with the glacier's mass balance. This study analyzes on the changes in glacier zones, mass balance, area and length, and streamflow in the nival glacial catchment over the past 60 years. It provides critical insight into the processes and mechanisms of glacier recession in response to climate change. The results are not only representative of those glaciers in the Tianshan mountains, but also for the continental-type throughout the world. The direct observation data form an essential basis for evaluating mountain glacier changes and the impact of glacier shrinkage on water resources in the interior drainage rivers within the vast arid and semi-arid land in northwestern China as well as Central Asia.     

天山东段冰雪消融与产汇流水文过程——以乌鲁木齐河源区为例

应用天山北坡乌鲁木齐河源区1 号冰川、空冰斗和总控3 个水文断面2011 年5-9 月每10min 实测水位数据、15 min 的气温、降水数据、1 号冰川消融及空冰斗区积雪观测数据,采用排除和不排除降水对冰雪消融产流影响的研究方法,系统分析了不同冰川覆盖率下水文断面冰雪消融特征及产汇流过程。结果表明：（1） 乌鲁木齐河源区3 个水文断面流量昼夜差异明显,1 号冰川水文断面白天径流大于夜晚径流,空冰斗和总控断面则相反;3 个断面流量亦具有显著日变化过程,且流量峰值大小和到来的时间存在差异。（2） 在排除与不排除降水两种天气影响下,1 号冰川最大流量滞后最高气温分别为1~3 h 和0~1 h;空冰斗断面分别为10~16 h和13 h,总控断面分别为5~11 h 和6~7 h,反映了1 号冰川从消融产流到汇流时间最短,空冰斗积雪消融产流时间最长,总控位于二者之间,同时亦反映伴随降水过程冰雪融水汇流迅速,即从产流到汇流时间有一定的缩短。（3） 影响3 个水文断面流量变化的因素不同,冰川区热量条件是影响1 号冰川水文断面的关键,1 号冰川在过去20 余年间,冰内、冰下排水道变得更为单一,对融水的阻滞和贮存作用弱化,融水汇流过程变得更为迅速。（4） 冰川覆盖山区流域水文断面在冰川消融期的流量过程线变化及最大流量与最高气温时滞变化规律在一定程度上对于认识冰川覆盖率有差异背景下的流域下垫面水系演化、冰雪消融过程及水文断面径流补给具有重要的指示意义。     

天山奎屯河哈希勒根51号冰川变化监测结果分析

哈希勒根51号冰川位于新疆奎屯市以南的天山依连哈比尔尕山北坡,即奎屯河上游支流哈希勒根河源区。1999年8月,在该冰川上布设了用于冰川变化观测研究的测杆18根;同时,在冰川外围测定了2个基本控制点和3个冰川末端变化观测控制点,运用GPS和全站仪等观测技术及测杆实测等方法,对该冰川进行了末端和运动速度变化的首次观测。嗣后,每年的8月底～9月初进行了重复观测;并在2000年和2006年对该冰川进行了测量制图。通过实测资料分析并对比20世纪60年代冰川状况,结果表明:42年来冰川末端累计退缩了84.51 m,其中,1964-1999年间退缩了49.00 m,年平均退缩量为1.40 m/a;1999-2006年间退缩了35.51 m,年平均退缩量5.07m/a。冰川面积减少了0.123 km~2或8.3%,其中,1964-2000年间减少了0.083 km~2;2000-2006年间减少了0.040 km~2。明显地反映出冰川末端退缩加剧和冰川面积减少增大的趋势。冰川年平均运动速度在1.53～3.05 m/a之间,并有逐年减小的趋势。     

Hydrological processes of glacier and snow melting and runoff in the Urumqi River source region,eastern Tianshan Mountains,China

Hydrological processes were compared, with and without the influence of precipitation on discharge, to identify the differences between glacierized and non-glacierized catchments in the Urumqi River source region, on the northern slope of the eastern Tianshan Mountains, during the melting season (May-September) in 2011. The study was based on hydrological data observed at 10-min intervals, meteorological data observed at 15-min intervals, and glacier melting and snow observations from the Empty Cirque, Zongkong, and Urumqi Glacier No.1 gauging stations. The results indicated that the discharge differed markedly among the three gauging stations. The daily discharge was more than the nightly discharge at the Glacier No.1 gauging station, which contrasted with the patterns observed at the Zongkong and Empty Cirque gauging stations. There was a clear daily variation in the discharge at the three gauging stations, with differences in the magnitude and duration of the peak discharge. When precipitation was not considered, the time-lags between the maximum discharge and the highest temperature were 1-3 h, 10-16 h, and 5-11 h at the Glacier No.1, Empty Cirque, and Zongkong gauging stations, respectively. When precipitation was taken into consideration, the corresponding time-lags were 0-1 h, 13 h, and 6-7 h, respectively. Therefore, the duration from the generation of discharge to confluence was the shortest in the glacierized catchment and the longest in the catchment where was mainly covered by snow. It was also shown that the hydrological process from the generation of discharge to confluence shortened when precipitation was considered. The factors influencing changes in the discharge among the three gauging stations were different. For Glacier No.1 station, the discharge was mainly controlled by heat conditions in the glacierized region, and the discharge displayed an accelerated growth when the temperature exceeded 5°C in the melt season. It was found that the englacial and subglacial drainage channel of Glacier No.1 had become simpler during the past 20 years. Its weaker retardance and storage of glacier melting water resulted in rapid discharge confluence. It was also shown that the discharge curve and the time-lag between the maximum discharge and the highest temperature could be used to reveal the evolution of the drainage system and the process of glacier and snow melting at different levels of glacier coverage.     

The surface velocity feature of Glacier No.1 at the headwater of Urumqi River, Tianshan Mountain

The movement of a glacier can redistribute glacier mass balance and change water and thermal conditions of the glacier.Thus,the glacier can maintain its dynamic balance.Surface velocity of a glacier is a basic feature of glacier movement.With successive monthly observations from 2006 to 2008,we obtained spatial and temporal variations for surface velocity of Glacier No.1 at the headwater of Urumqi River,Tianshan Mountain.Dynamic simulation was used to verify the findings.Results show that altitudinal distribution of glacier velocity was influenced by synthetic effects such as glacier thickness,slope,and bedrock morphology.However,seasonal variation was influenced by changing glacier thickness.     

中国典型季风海洋性冰川区雪坑中主要阴、阳离子的来源研究

Snowpacks samples were colleted from two glaciers： Baishui No.1 glacier and Hailuogou No.1 glacier in June, 2006. The method of sea-salt ions tracer, correlation analysis and trend analysis were used in this research in order to confirm the source of main ions, it is indicated that Na^＋ is mainly from marine moisture and other ions mainly originate from land dust. The non-marine source percent of Cl^-, NO3^- , SO4^2-, K^＋, Ca^2＋ and Mg^2＋ is 52%, 99%, 100%, 98%, 99.9% and 83%, respectively, in Hailuogou No.1 glacier, while the corresponding value in Baishui No.1 glacier is 68%, 99%, 100%, 98%, 99% and 59%. The non-marine source of ions is from dust of Central Asia arid regions carried by westerly circulation and the plateau borne-areas with Qinghai-Tibet Plateau winter monsoon in two glacial areas. However, the import of local dust in glacial area has made a great contribution to ions concentration in Baishui No.1 glacier, which accounts for the reason why the ions concentration in Baishui No.1 glacier is much higher than that of Hailuogou No.1 glacier. It is obvious that the source of each ion is different between Hailuogou No.1 glacier and Baishui No.1 glacier. There are three reasons which can explain it： firstly, the difference in the internal environment of glacial area, such as lithology, mountain-valley wind system, topographical relief and so on; secondly, the influence exerted by ions elution in snowpacks section, and ions elution in Hailuogou No.1 glacier is very strong; and thirdly, the difference caused due to varying ions transporting styles, deposition modes, chemical characteristics and post-ions-deposition process.     

Study on diversity and temporal-spatial characteristics of eukaryotic microorganisms on Glacier No.1 at the Urumqi River Head, Tianshan

Surface snow samples of different altitudes and snow pit samples were collected from Glacier No.1 at the Urumqi River Head, Tianshan. Denaturing gradient gel electrophoresis (DGGE) was used to examine the diversity and temporal-spatial characteristics of eukaryotic microorganisms with different altitudes and depths. Results show that the eukaryotic microorganisms belong to four kingdoms—Viridiplantae, Fungi, Amoebozoa, and Alveolata. Among them, algae (especially Chlamydomonadales) were the dominant group. The diversity of eukaryotic microorganisms was negatively correlated with altitude and accumulation time, but positively correlated with δ¹⁸O values. These results indicate that temperature is the main factor for the temporal- spatial change of eukaryotic microorganisms, and the diversity of eukaryotic microorganisms could be an index for climate and environmental change.     

Source of major anions and cations of snowpacks in Hailuogou No.1 glacier, Mt. Gongga and Baishui No.1 glacier, Mt. Yulong

Snowpacks samples were colleted from two glaciers: Baishui No.1 glacier and Hailuogou No.1 glacier in June, 2006. The method of sea-salt ions tracer, correlation analysis and trend analysis were used in this research in order to confirm the source of main ions, it is indicated that Na+ is mainly from marine moisture and other ions mainly originate from land dust. The non-marine source percent of Cl-, NO-3, SO2-4, K+, Ca2+ and Mg2+ is 52%, 99%, 100%, 98%, 99.9% and 83%, respectively, in Hailuogou No.1 glacier, while the corresponding value in Baishui No.1 glacier is 68%, 99%, 100%, 98%, 99% and 59%. The non-marine source of ions is from dust of Central Asia arid regions carried by westerly circulation and the plateau borne-areas with Qinghai-Tibet Plateau winter monsoon in two glacial areas. How-ever, the import of local dust in glacial area has made a great contribution to ions concentra-tion in Baishui No.1 glacier, which accounts for the reason why the ions concentration in Bai-shui No.1 glacier is much higher than that of Hailuogou No.1 glacier. It is obvious that the source of each ion is different between Hailuogou No.1 glacier and Baishui No.1 glacier. There are three reasons which can explain it: firstly, the difference in the internal environment of glacial area, such as lithology, mountain-valley wind system, topographical relief and so on; secondly, the influence exerted by ions elution in snowpacks section, and ions elution in Hailuogou No.1 glacier is very strong; and thirdly, the difference caused due to varying ions transporting styles, deposition modes, chemical characteristics and post-ions-deposition process.