Topography Controls Variability in Circumpolar Permafrost Thaw Pond Expansion

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Journal of Geophysical Research: Earth Surface Pub Date : 2024-09-18 DOI:10.1029/2024JF007675
C. J. Abolt, A. L. Atchley, D. R. Harp, M. T. Jorgenson, C. Witharana, W. R. Bolton, J. Schwenk, T. Rettelbach, G. Grosse, J. Boike, I. Nitze, A. K. Liljedahl, C. T. Rumpca, C. J. Wilson, K. E. Bennett
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Abstract

One of the most conspicuous signals of climate change in high-latitude tundra is the expansion of ice wedge thermokarst pools. These small but abundant water features form rapidly in depressions caused by the melting of ice wedges (i.e., meter-scale bodies of ice embedded within the top of the permafrost). Pool expansion impacts subsequent thaw rates through a series of complex positive and negative feedbacks which play out over timescales of decades and may accelerate carbon release from the underlying sediments. Although many local observations of ice wedge thermokarst pool expansion have been documented, analyses at continental to pan-Arctic scales have been rare, hindering efforts to project how strongly this process may impact the global carbon cycle. Here we present one of the most geographically extensive and temporally dense records yet compiled of recent pool expansion, in which changes to pool area from 2008 to 2020 were quantified through satellite-image analysis at 27 survey areas (measuring 10–35 km2 each, or 400 km2 in total) dispersed throughout the circumpolar tundra. The results revealed instances of rapid expansion at 44% ( ± $\pm $ 15%) of survey areas. Considered alone, the extent of departures from historical mean air temperatures did not account for between site variation in rates of change to pool area. Pool growth was most clearly associated with upland (i.e., hilly) terrain and elevated silt content at soil depths greater than one meter. These findings suggest that, at short time scales, pedologic and geomorphologic conditions may exert greater control on pool dynamics in the warming Arctic than spatial variability in the rate of air temperature increases.

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地形控制着极圈冻土解冻池扩展的变异性
高纬度冻土带气候变化最明显的信号之一是冰楔热流池的扩大。冰楔(即嵌入永久冻土顶部的米级冰体)融化造成的洼地迅速形成了这些小而丰富的水域。水池的扩张会通过一系列复杂的正反馈作用影响随后的解冻速度,其时间尺度可达数十年,并可能加速底层沉积物的碳释放。尽管已经有许多关于冰楔热卡斯特池扩张的局部观测记录,但从大陆到泛北极尺度的分析却很少见,这阻碍了预测这一过程可能对全球碳循环产生多大影响的工作。在这里,我们展示了迄今为止关于近期水池扩张的地理范围最广、时间最密集的记录之一,其中通过卫星图像分析,量化了从 2008 年到 2020 年水池面积的变化,这些水池分布在环北极苔原的 27 个调查区(每个调查区面积为 10-35 平方公里,总面积为 400 平方公里)。结果显示,44%(± $\pm$15%)的调查区域出现了快速扩张的情况。单独考虑,偏离历史平均气温的程度并不能解释水池面积变化率在不同地点之间的差异。水池面积的增长与高地(即丘陵)地形和土壤深度超过一米的淤泥含量升高有最明显的关系。这些研究结果表明,在短时间内,与气温上升速度的空间变化相比,在北极变暖的情况下,土壤学和地貌条件对水池动态的控制可能更大。
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来源期刊
Journal of Geophysical Research: Earth Surface
Journal of Geophysical Research: Earth Surface Earth and Planetary Sciences-Earth-Surface Processes
CiteScore
6.30
自引率
10.30%
发文量
162
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