60,000 years of hydrologic connectivity on the Australian dryland margins: the case of the Willandra Lakes World Heritage Area
- 1University of Tübingen, Geosciences, Geosciences, Tübingen, Germany (kathryn.fitzsimmons@uni-tuebingen.de; tobias.lauer@uni-tuebingen.de; kanchan.mishra@uni-tuebingen.de)
- 2Department of Geosciences, University of Potsdam, Potsdam-Golm, Germany (markus.lothar.fischer@uni-potsdam.de)
- 3School of Earth, Atmospheric and Life Sciences, University of Wollongong, Wollongong, Australia (cwallace@uow.edu.au)
- 4Department of Geography, University of Sheffield, Sheffield, UK (Ed.Rhodes@Sheffield.ac.uk)
- 5School of Geography and the Environment, University of Oxford, Oxford, UK (maike.nowatzki@ouce.ox.ac.uk)
- 6Department of Archaeology and History, La Trobe University, Melbourne, Australia (n.stern@latrobe.edu.au)
Australia is big, flat, old and arid: it is the driest inhabited continent on Earth. The catastrophic flooding of recent years has demonstrated not only the potential for extreme conditions at both ends of the hydroclimatic scale, but also how little we understand of the interplay between climatic, hydrological, and surface-process mechanisms affecting this part of the world. We know still less about long-term hydrological dynamics, particularly for the dry inland where water resources are scarce and land surfaces are susceptible to erosion, requiring careful management.
Records of past hydrological variability can help inform us about changing hydroclimate states and their impact on the land surface. The Willandra lakes system, located on the desert margins of southeastern Australia, is one of the few dryland areas which preserves long-term sedimentary records of hydrologic change. The headwaters of these lakes lie in the temperate highlands hundreds of kilometres to the east; as a result, lake filling and drying reflects the interaction between rainfall in the watershed and hydrologic connectivity across the catchment and between the lakes. Environmental change in the Willandra is recorded in the sediments of the lake shoreline dunes, preserved as semi-continuous deposition of different lake facies over 60,000 years.
Here we investigate long-term hydrologic connectivity across the Willandra lakes and their catchment. Our approach uses a novel integration of lake-level reconstruction based on lunette sedimentology, stratigraphy and luminescence geochronology, with hydrologic and palaeoclimatic modelling of key event time slices over the last 60 ky. We characterize the land-surface response to various hydroclimate states, so improving our understanding of dryland atmosphere-hydrosphere interactions.
How to cite: Fitzsimmons, K., Fischer, M., Murray-Wallace, C., Rhodes, E., Lauer, T., Nowatzki, M., Mishra, K., and Stern, N.: 60,000 years of hydrologic connectivity on the Australian dryland margins: the case of the Willandra Lakes World Heritage Area, EGU General Assembly 2024, Vienna, Austria, 14–19 Apr 2024, EGU24-9899, https://doi.org/10.5194/egusphere-egu24-9899, 2024.