Long-term hydrologic connectivity on the Australian dryland margins: Evidence from the Willandra Lakes World Heritage Area over the last 60 ky

IF 1.9 3区地球科学 Q3 GEOGRAPHY, PHYSICAL

Journal of Quaternary Science Pub Date : 2025-04-16 DOI:10.1002/jqs.3717

Kathryn E. Fitzsimmons, Markus L. Fischer, Tegan Smith, Tobias Lauer, Maike Nowatzki, Kanchan Mishra, Colin V. Murray-Wallace

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Abstract

The semi-arid Australian continental inland is increasingly subject to climatic extremes such as drought and flooding. Combined with the exceptionally low topographic relief characteristic of this region, hydroclimatic extremes can have an enormous impact on the land surface. Nevertheless our understanding of dryland hydrologic connectivity and earth-surface response remains poorly understood and largely unquantified. Here we investigate the impact of past hydroclimate on the semi-arid Willandra Lakes over the last 60 ky, integrating sediment-based chronologies for filling and drying of multiple basins with water-flux modelling and reconstruction of palaeoclimate parameters. We quantify the threshold inflow volume required to fill the lake system to 2 km³. We establish that prior to 25 ka, permanent lakes persisted for protracted periods of time in response to increased catchment precipitation, consistent with regional geomorphic indicators for wetter conditions. By contrast, the Last Glacial Maximum (LGM) oversaw rapid couplets of lake filling and drying despite lower precipitation, temperature, and increasing evaporation. We propose that seasonal snow melt from the highland headwaters during this cold phase, coupled with increased effective runoff due to reduced vegetation cover, was responsible for the large quantities of water entering the system at this time.

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澳大利亚旱地边缘的长期水文连通性：过去60年来来自威兰德拉湖世界遗产区的证据

半干旱的澳大利亚内陆大陆正日益受到干旱和洪水等极端气候的影响。再加上该地区地形起伏异常低的特点，极端水文气候可能对陆地表面产生巨大影响。然而，我们对旱地水文连通性和地表响应的理解仍然很差，而且在很大程度上没有量化。在此，我们将多个盆地的填满和干燥的沉积物年代学与水通量模拟和古气候参数的重建相结合，研究了过去60天水文气候对半干旱威兰德拉湖的影响。我们将填满湖泊系统所需的阈值入水量量化为2立方公里。我们确定，在25 ka之前，永久性湖泊持续了很长一段时间，以响应集水区降水的增加，与更湿润条件的区域地貌指标一致。相比之下，末次盛冰期（LGM）尽管降水减少、温度降低、蒸发量增加，但湖泊填满和干燥的耦合速度很快。我们认为，在这个寒冷阶段，来自高原源头的季节性融雪，加上由于植被覆盖减少而增加的有效径流，是此时大量水进入系统的原因。

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来源期刊

Journal of Quaternary Science 地学-地球科学综合

CiteScore

4.70

自引率

8.70%

发文量

审稿时长

6-12 weeks

期刊介绍： The Journal of Quaternary Science publishes original papers on any field of Quaternary research, and aims to promote a wider appreciation and deeper understanding of the earth''s history during the last 2.58 million years. Papers from a wide range of disciplines appear in JQS including, for example, Archaeology, Botany, Climatology, Geochemistry, Geochronology, Geology, Geomorphology, Geophysics, Glaciology, Limnology, Oceanography, Palaeoceanography, Palaeoclimatology, Palaeoecology, Palaeontology, Soil Science and Zoology. The journal particularly welcomes papers reporting the results of interdisciplinary or multidisciplinary research which are of wide international interest to Quaternary scientists. Short communications and correspondence relating to views and information contained in JQS may also be considered for publication.