美国犹他州拉萨尔山和乌因塔山岩冰川的当代运动

IF 2.9 Q2 GEOGRAPHY, PHYSICAL Quaternary Science Advances Pub Date : 2024-04-10 DOI:10.1016/j.qsa.2024.100188
Jeffrey S. Munroe , Alexander L. Handwerger
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引用次数: 0

摘要

岩石冰川是美国西部山区常见的地貌。活跃的岩石冰川的运动是冰含量的一个关键指标,与气候和水文系统息息相关。在这里,我们通过重复差分 GPS 勘测,对犹他州拉萨尔和乌因塔山的六条岩石冰川的运动进行了量化。我们分别于 2021 年 9 月、2022 年 7 月、2022 年 9 月和 2023 年 7 月对每条岩石冰川上的 10-41 个点组成的网络进行了勘测。我们发现,所有地貌都在移动,平均年移动速度为 1.5 ± 0.8 至 18.5 ± 7.5 厘米/年。岩石冰川在夏季的移动速度比冬季快 3 倍,在降雪量高于平均水平的冬季之后,2023 年的移动速度更大,这强调了液态水供应的作用。2021-22 年冬季各点的运动速度与 2022-23 年冬季的运动速度呈正相关,这表明运动的空间变化不是随机的,而是反映了每条岩石冰川的内部特性。冬季测量的雪底温度和夏季泉水温度表明,这些岩石冰川含有现代永久冻土。放射性碳数据记录了一条岩冰川在小冰河时期的前进过程。我们的全球定位系统数据集揭示了岩冰川运动的复杂模式,我们建立的勘测点网络将成为探测这些山脉未来冰冻圈变化的宝贵基线。
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Contemporary movement of rock glaciers in the La Sal and Uinta Mountains, Utah, USA

Rock glaciers are common landforms in mountainous areas of the western US. The motion of active rock glaciers is a key indicator of ice content, offering connections to climate and hydrologic systems. Here, we quantified the movement of six rock glaciers in the La Sal and Uinta Mountains of Utah through repeat differential GPS surveying. Networks of 10–41 points on each rock glacier were surveyed in September 2021; July 2022; September 2022; and July 2023. We found that all features are moving with average annual rates of motion from 1.5 ± 0.8 to 18.5 ± 7.5 cm/yr. Rock glaciers move up to 3× faster in the summer than in the winter, and rates of motion were greater in 2023 after a winter with above-average snowfall, emphasizing the role of liquid water availability. Velocities of individual points in the winter of 2021–22 are positively correlated with velocities during the winter of 2022–23, suggesting that spatial variability of motion is not stochastic, but rather reflects internal properties of each rock glacier. Bottom temperature of snow measurements during winter, and the temperature of springs discharging water in summer, suggest that these rock glaciers contain modern permafrost. Radiocarbon data document advance of one rock glacier during the Little Ice Age. Our GPS dataset reveals complicated patterns of rock glacier movement, and the network of survey points we established will be a valuable baseline for detecting future cryosphere change in these mountains.

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来源期刊
Quaternary Science Advances
Quaternary Science Advances Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
4.00
自引率
13.30%
发文量
16
审稿时长
61 days
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