Robust Reconstruction of Historical Climate Change From Permafrost Boreholes

IF 3.5 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Journal of Geophysical Research: Earth Surface Pub Date : 2024-07-09 DOI:10.1029/2024JF007734
Brian Groenke, Moritz Langer, Frederieke Miesner, Sebastian Westermann, Guillermo Gallego, Julia Boike
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Abstract

Reconstructing historical climate change from deep ground temperature measurements in cold regions is often complicated by the presence of permafrost. Existing methods are typically unable to account for latent heat effects due to the freezing and thawing of the active layer. In this work, we propose a novel method for reconstructing historical ground surface temperature (GST) from borehole temperature measurements that accounts for seasonal thawing and refreezing of the active layer. Our method couples a recently developed fast numerical modeling scheme for two-phase heat transport in permafrost soils with an ensemble-based method for approximate Bayesian inference. We evaluate our method on two synthetic test cases covering both cold and warm permafrost conditions as well as using real data from a 100 m deep borehole on Sardakh Island in northeastern Siberia. Our analysis of the Sardakh Island borehole data confirms previous findings that GST in the region have likely risen by 5–9°C between the pre-industrial period of 1750–1855 and 2012. We also show that latent heat effects due to seasonal freeze-thaw have a substantial impact on the resulting reconstructed surface temperatures. We find that neglecting the thermal dynamics of the active layer can result in biases of roughly −1°C in cold conditions (i.e., mean annual ground temperature below −5°C) and as much as −2.6°C in warmer conditions where substantial active layer thickening (>200 cm) has occurred. Our results highlight the importance of considering seasonal freeze-thaw in GST reconstructions from permafrost boreholes.

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从永久冻土钻孔中重建历史气候变化的稳健性
根据寒冷地区的深层地温测量结果重建历史气候变化往往因永久冻土的存在而变得复杂。现有方法通常无法考虑活动层冻结和解冻所产生的潜热效应。在这项工作中,我们提出了一种根据钻孔温度测量重建历史地表温度(GST)的新方法,该方法考虑了活动层的季节性解冻和再冻结。我们的方法将最近开发的永久冻土两相热传导快速数值建模方案与基于集合的近似贝叶斯推断方法相结合。我们在两个涵盖冷冻和暖冻土条件的合成测试案例中,以及使用来自西伯利亚东北部萨尔达赫岛 100 米深钻孔的真实数据,对我们的方法进行了评估。我们对萨达赫岛钻孔数据的分析证实了之前的研究结果,即从 1750-1855 年工业化前时期到 2012 年,该地区的 GST 可能上升了 5-9°C 。我们还表明,季节性冻融导致的潜热效应对重建的地表温度有很大影响。我们发现,在寒冷条件下(即年平均地面温度低于-5°C),忽略活动层的热动力学会导致大约-1°C的偏差,而在活动层大幅增厚(200厘米)的温暖条件下,偏差则高达-2.6°C。我们的研究结果突出表明,在从永久冻土钻孔中重建全球平均温度时,考虑季节性冻融非常重要。
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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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