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快速冰川流动的物理条件:3. 西格陵兰斯托尔冰川上季节性演变的冰体变形

Physical Conditions of Fast Glacier Flow: 3. Seasonally-Evolving Ice Deformation on Store Glacier, West Greenland.

作者信息

Young T J, Christoffersen P, Doyle S H, Nicholls K W, Stewart C L, Hubbard B, Hubbard A, Lok L B, Brennan P V, Benn D I, Luckman A, Bougamont M

机构信息

Scott Polar Research Institute University of Cambridge Cambridge UK.

British Antarctic Survey, National Environmental Research Council Cambridge UK.

出版信息

J Geophys Res Earth Surf. 2019 Jan;124(1):245-267. doi: 10.1029/2018JF004821. Epub 2019 Jan 30.

DOI:10.1029/2018JF004821
PMID:31007992
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6472443/
Abstract

Temporal variations in ice sheet flow directly impact the internal structure within ice sheets through englacial deformation. Large-scale changes in the vertical stratigraphy within ice sheets have been previously conducted on centennial to millennial timescales; however, intra-annual changes in the morphology of internal layers have yet to be explored. Over a period of 2 years, we use autonomous phase-sensitive radio-echo sounding to track the daily displacement of internal layers on Store Glacier, West Greenland, to millimeter accuracy. At a site located ∼30 km from the calving terminus, where the ice is ∼600 m thick and flows at ∼700 m/a, we measure distinct seasonal variations in vertical velocities and vertical strain rates over a 2-year period. Prior to the melt season (March-June), we observe increasingly nonlinear englacial deformation with negative vertical strain rates (i.e., strain thinning) in the upper half of the ice column of approximately -0.03 a, whereas the ice below thickens under vertical strain reaching up to +0.16 a. Early in the melt season (June-July), vertical thinning gradually ceases as the glacier increasingly thickens. During late summer to midwinter (August-February), vertical thickening occurs linearly throughout the entire ice column, with strain rates averaging 0.016 a. We show that these complex variations are unrelated to topographic setting and localized basal slip and hypothesize that this seasonality is driven by far-field perturbations in the glacier's force balance, in this case generated by variations in basal hydrology near the glacier's terminus and propagated tens of kilometers upstream through transient basal lubrication longitudinal coupling.

摘要

冰盖流动的时间变化通过冰内变形直接影响冰盖内部结构。此前已在百年至千年时间尺度上对冰盖内垂直地层的大规模变化进行了研究;然而,内部冰层形态的年内变化尚未得到探索。在两年时间里,我们使用自主相位敏感无线电回波探测技术,以毫米级精度追踪西格陵兰岛斯托尔冰川内部冰层的每日位移。在距离崩解终点约30公里的一个地点,那里冰层厚度约600米,流速约700米/年,我们在两年时间里测量了垂直速度和垂直应变率的明显季节性变化。在融化季节(3月至6月)之前,我们观察到冰柱上半部分的冰内变形越来越非线性,垂直应变率为负(即应变变薄),约为-0.03/a,而下方的冰在垂直应变下增厚,达到+0.16/a。在融化季节早期(6月至7月),随着冰川不断增厚,垂直变薄逐渐停止。在夏末至仲冬(8月至2月)期间,整个冰柱都出现线性垂直增厚,应变率平均为0.016/a。我们表明,这些复杂变化与地形环境和局部基底滑动无关,并推测这种季节性变化是由冰川力平衡中的远场扰动驱动的,在这种情况下,是由冰川终点附近基底水文变化产生的,并通过瞬态基底润滑纵向耦合向上游传播数十公里。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/c0e2/6472443/26fe5dc3544c/JGRF-124-245-g009.jpg
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