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Quantitative assessment of the oxygen isotope composition of fish otoliths from Lake Mungo, Australia

Published online by Cambridge University Press:  01 February 2021

Kelsie Long Open the ORCID record for Kelsie Long [Opens in a new window] ,
David Heslop  and
Eelco J. Rohling
Kelsie Long*
Affiliation:
Research School of Earth Sciences, Australian National University, 142 Mills Road, Canberra, ACT 2601, Australia School of Culture, History and Language, Australian National University, H.C. Coombs building, 9 Fellows Road, Canberra, ACT 2601, Australia ARC Centre of Excellence for Australian Biodiversity and Heritage, Australian National University, Canberra, ACT 2601, Australia
David Heslop
Affiliation:
Research School of Earth Sciences, Australian National University, 142 Mills Road, Canberra, ACT 2601, Australia
Eelco J. Rohling
Affiliation:
Research School of Earth Sciences, Australian National University, 142 Mills Road, Canberra, ACT 2601, Australia School of Ocean and Earth Science, University of Southampton, National Oceanography Centre, Southampton, SO15 3ZH, UK
*
*Corresponding author e-mail address: [email protected].
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Abstract

The Willandra Lakes region is a series of once interconnected and now-dry lake basins in the arid zone of southeastern Australia. It is a UNESCO World Heritage Site of cultural, archaeological, and geological significance, preserving records of Aboriginal occupation and environmental change stretching back to at least 50 ka. Linking the archaeology with the commensurate palaeoenvironmental information is complicated by the millennial time spans represented by the past hydrological record preserved in the sediment vs. the subdecadal evidence of each archaeological site. Oxygen isotope records across annual growth rings of fish otoliths (ear stones) can elucidate flooding and drying regimes on subannual scales. Otoliths from hearth sites (fireplaces) link lake hydrology with people eating fish on the lakeshore. Oxygen isotopic trends in hearth otoliths from the last glacial maximum (LGM) were previously interpreted in terms of high evaporation under dry conditions. However, this ignored hydrology-driven changes in water δ18O. Here, a mass balance model is constructed to test the effect lake desiccation has on water δ18O and how this compares with the LGM otolith records. Based on this modelling, we suggest that Lake Mungo otolith signatures are better explained by evaporation acting on full lakes rather than by lake drying.

Keywords

QuaternaryOxygen isotopesWillandra LakesOtolithsArid zone
Type
Research Article
Information
Quaternary Research , Volume 102 , July 2021 , pp. 234 - 246
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Copyright
Copyright © University of Washington. Published by Cambridge University Press, 2021

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References

REFERENCES

Allen, H., Holdaway, S., 2009. The archaeology of Mungo and the Willandra Lakes: looking back, looking forward. Archaeology in Oceania 44, 96106.CrossRefGoogle Scholar
Anderson, J.R., Morison, A.K., Ray, D.J., 1992. Validation of the use of thin-sectioned otoliths for determining the age and growth of golden perch, Macquaria ambigua (Perciformes: Percichthyidae), in the lower Murray-Darling Basin, Australia. Australian Journal of Marine and Freshwater Resources 43, 11031128.CrossRefGoogle Scholar
Andrus, C.F.T., Crowe, D.E., 2002. Alteration of otolith aragonite: effects of prehistoric cooking methods on otolith chemistry. Journal of Archaeological Science 29, 291299.CrossRefGoogle Scholar
Andrus, C.F.T., Crowe, D.E., Sandweiss, D.H., Reitz, E.J., Romanek, C.S., 2002. Otolith delta 18O record of mid-Holocene sea surface temperatures in Peru. Science 295, 15081511.CrossRefGoogle ScholarPubMed
Australian Government Bureau of Meteorology, 2020a. Monthly Rainfall Data: Pooncarie (Mulurulu Station) (accessed July 16, 2020). http://www.bom.gov.au/jsp/ncc/cdio/weatherData/av?p_nccObsCode=139&p_display_type=dataFile&p_startYear=&p_c=&p_stn_num=047024.Google Scholar
Australian Government Bureau of Meteorology, 2020b. Average Annual, Monthly and Seasonal Evaporation (accessed November 7, 2020). http://www.bom.gov.au/jsp/ncc/climate_averages/evaporation/index.jsp.Google Scholar
Australian Government Bureau of Meteorology, 2020c. Monthly Climate Statistics: Mildura Airport (accessed July 22, 2020). http://www.bom.gov.au/climate/averages/tables/cw_076031.shtml.Google Scholar
Barrows, T.T., Fitzsimmons, K.E., Mills, S.C., Tumney, J., Pappin, D., Stern, N., 2020. Late Pleistocene lake level history of Lake Mungo, Australia. Quaternary Science Reviews 238, 106338.CrossRefGoogle Scholar
Barrows, T.T., Juggins, S., De Deckker, P., Calvo, E., Pelejero, C., 2007. Long-term sea surface temperature and climate change in the Australian-New Zealand region. Paleoceanography 22, PA2215.CrossRefGoogle Scholar
Battaglene, S., Prokop, F., 1987. Golden Perch, AGFACTS A3.2.2. N.S.W Department of Agriculture, Sydney, Australia.Google Scholar
Bowler, J.M., 1998. Willandra Lakes revisited: environmental framework for human occupation. Archaeology in Oceania 33, 120155.CrossRefGoogle Scholar
Bowler, J.M., Gillespie, R., Johnston, H., Boljkovac, K., Bolijkovac, K., 2012. Wind v water: glacial maximum records from the Willandra Lakes. In: Haberle, S.G., David, B. (Eds.), Peopled Landscapes: Archaeological and Biogeographic Approaches to Landscapes. Terra Australis Series 34. ANU Press, Canberra, pp. 271296.Google Scholar
Bowler, J.M., Hope, G.S., Jennings, J.N., Singh, G., Walker, D., 1976. Late Quaternary climates of Australia and New Guinea. Quaternary Research 6, 359394.CrossRefGoogle Scholar
Bowler, J.M., Johnston, H., Olley, J.M., Prescott, J.R., Roberts, R.G., Shawcross, W., Spooner, N.A., 2003. New ages for human occupation and climatic change at Lake Mungo, Australia. Nature 421, 837840.CrossRefGoogle ScholarPubMed
Bowler, J.M., Jones, R., Allen, H., Thorne, A.G., 1970. Pleistocene human remains from Australia: a living site and human cremation from Lake Mungo, western New South Wales. World Archaeology 2, 3960.CrossRefGoogle ScholarPubMed
Box, G.E.P., 1976. Science and statistics. Journal of the American Statistical Association 71, 791799.CrossRefGoogle Scholar
Cadwallader, P.L., 1979. Distribution of native and introduced fish in the Seven Creeks River system, Victoria. Australian Journal of Ecology 4, 361385.CrossRefGoogle Scholar
Cadwallader, P.L., Backhouse, G.N., 1983. A Guide to the Freshwater Fish of Victoria, Melbourne, Victoria: Victorian Government Printing Office, on behalf of the Fisheries and Wildlife Division, Ministry for Conservation, 1–249.Google Scholar
Campana, S.E., 1999. Chemistry and composition of fish otoliths: pathways, mechanisms and applications. Marine Ecology Progress Series 188, 263297.CrossRefGoogle Scholar
Craig, H., Gordon, L., 1965. Deuterium and oxygen-18 variations in the ocean and the marine atmosphere. In: Tongiorgi, E. (Ed.), Stable Isotopes in Oceanographic Studies and Paleotemperatures. Laboratorio di Geologia Nucleare, Pisa, Italy.Google Scholar
Craig, H., Gordon, L.I., Horibe, Y., 1963. Isotopic exchange effects in the evaporation of water: 1, low-temperature experimental results. Journal of Geophysical Research 68, 50795087.CrossRefGoogle Scholar
Dinçer, T., 1968. The use of oxygen 18 and deuterium concentrations in the water balance of lakes. Water Resources Research 4, 12891306.CrossRefGoogle Scholar
Disspain, M.C.F., Ulm, S., Izzo, C., Gillanders, B.M., 2016. Do fish remains provide reliable palaeoenvironmental records? An examination of the effects of cooking on the morphology and chemistry of fish otoliths, vertebrae and scales. Journal of Archaeological Science 74, 4559.CrossRefGoogle Scholar
Dufour, E., Van Neer, W., Vermeersch, P.M., Patterson, W.P., 2018. Hydroclimatic conditions and fishing practices at Late Paleolithic Makhadma 4 (Egypt) inferred from stable isotope analysis of otoliths. Quaternary International 471, 190202.CrossRefGoogle Scholar
Fitzsimmons, K., Stern, N., Murray-Wallace, C.V., 2014. Depositional history and archaeology of the central Lake Mungo lunette, Willandra Lakes, southeast Australia. Journal of Archaeological Science 41, 349364.CrossRefGoogle Scholar
Froehlich, K.F.O., Gonfiantini, R., Rozanski, K., 2005. Isotopes in lake studies: a historical perspective. In: Aggarwal, P.K., Gat, J.R., Froehlich, K.F.O. (Eds.), Isotopes in the Water Cycle: Past, Present and Future of a Developing Science. Springer-Verlag, Berlin, pp. 139150.CrossRefGoogle Scholar
Gat, J.R., 1995. Stable isotopes of fresh and saline lakes. Physics and Chemistry of Lakes 60, 139163.CrossRefGoogle Scholar
Gat, J.R., Bowser, C., 1991. The heavy isotope enrichment of water in coupled evaporative systems. In: Tayor, P., O'Neill, J.P., Kaplan, I.R. (Eds.), Stable Isotope Geochemistry: A Tribute to Samuel Epstein Special Pu. Geochemical Society, Washington, D.C., pp. 159168.Google Scholar
Geffen, A.J., Høie, H., Folkvord, A., Hufthammer, A.K., Andersson, C., Ninnemann, U., Pedersen, R.B., Nedreaas, K., 2011. High-latitude climate variability and its effect on fisheries resources as revealed by fossil cod otoliths. ICES Journal of Marine Science 68, 10811089.CrossRefGoogle Scholar
Gibson, J.J., Birks, S.J., Yi, Y., 2016. Stable isotope mass balance of lakes: a contemporary perspective. Quaternary Science Reviews 131, 316328.CrossRefGoogle Scholar
Gibson, J.J., Edwards, T.W.D., 2002. Regional water balance trends and evaporation-transpiration partitioning from a stable isotope survey of lakes in northern Canada. Global Biogeochemical Cycles 16, 1026.CrossRefGoogle Scholar
Gibson, J.J., Edwards, T.W.D., Prowse, T.D., 1996. Development and validation of an isotopic method for estimating lake evaporation. Hydrological Processes 10, 13691382.3.0.CO;2-J>CrossRefGoogle Scholar
Gibson, J.J., Reid, R., 2014. Water balance along a chain of tundra lakes: a 20-year isotopic perspective. Journal of Hydrology 519, 21482164.CrossRefGoogle Scholar
Gonfiantini, R., 1986. Environmental isotopes in lake studies. In: Fritz, P., Fontes, J.C. (Eds.), Handbook of Environmental Isotope Geochemistry. Vol. 2, The Terrestrial Environment, B. Elsevier, Amsterdam, The Netherlands, pp. 113168.Google Scholar
Gonfiantini, R., Wassenaar, L.I., Araguas-Araguas, L., Aggarwal, P.K., 2018. A unified Craig-Gordon isotope model of stable hydrogen and oxygen isotope fractionation during fresh or saltwater evaporation. Geochimica et Cosmochimica Acta 235, 224236.CrossRefGoogle Scholar
Hesse, P.P., Magee, J.W., van der Kaars, S., 2004. Late Quaternary climates of the Australian arid zone: a review. Quaternary International 118–119, 87102.CrossRefGoogle Scholar
Hughes, C.E., Stone, D.J.M., Gibson, J.J., Meredith, K.T., Sadek, M.A., Cendon, D.I., Hankin, S.I., Hollins, S.E., Morrison, T.N., 2012. Stable water isotope investigation of the Barwon-Darling River system, Australia. In: Monitoring Isotopes in Rivers: Creation of the Global Network of Isotopes in Rivers (GNIR). Results of a Coordinated Research Project 2002–2006. International Atomic Energy Agency, Vienna, pp. 97110.Google Scholar
Humphries, P., King, A., Koehn, J., 1999. Fish, flows and flood plains: links between freshwater fishes and their environment in the Murray-Darling River system, Australia. Environmental Biology of Fishes 56, 129151.CrossRefGoogle Scholar
Jankowski, N.R., Stern, N., Lachlan, T.J., Jacobs, Z., 2020. A high-resolution late Quaternary depositional history and chronology for the southern portion of the Lake Mungo lunette, semi-arid Australia. Quaternary Science Reviews 233, 106224.CrossRefGoogle Scholar
Jones, M.D., 2013. What do we mean by wet? Geoarchaeology and the reconstruction of water availability. Quaternary International 308–309, 7679.CrossRefGoogle Scholar
Jones, M.D., Cuthbert, M.O., Leng, M.J., McGowan, S., Mariethoz, G., Arrowsmith, C., Sloane, H.J., Humphrey, K.K., Cross, I., 2016. Comparisons of observed and modelled lake δ18O variability. Quaternary Science Reviews 131, 329340.CrossRefGoogle Scholar
Jones, M.D., Leng, M.J., Roberts, C.N., Türkeş, M., Moyeed, R., 2005. A coupled calibration and modelling approach to the understanding of dry-land lake oxygen isotope records. Journal of Paleolimnology 34, 391411.CrossRefGoogle Scholar
Kalish, J.M., 1991. Oxygen and carbon stable isotopes in the otoliths of wild and laboratory-reared Australian salmon (Arripis trutta). Marine Biology 47, 3747.CrossRefGoogle Scholar
Kemp, J., Rhodes, E.J., 2010. Episodic fluvial activity of inland rivers in southeastern Australia: palaeochannel systems and terraces of the Lachlan River. Quaternary Science Reviews 29, 732752.CrossRefGoogle Scholar
Kerr, L., Secor, D., Kraus, R., 2007. Stable isotope (δ13C and δ18O) and Sr/Ca composition of otoliths as proxies for environmental salinity experienced by an estuarine fish. Marine Ecology Progress Series 349, 245253.CrossRefGoogle Scholar
King, A.J., Tonkin, Z., Mahoney, J., 2009. Environmental flow enhances native fish spawning and recruitment in the Murray River, Australia. River Research and Applications 25, 12051218.CrossRefGoogle Scholar
Lacey, J.H., Jones, M.D., 2018. Quantitative reconstruction of early Holocene and last glacial climate on the Balkan peninsula using coupled hydrological and isotope mass balance modelling. Quaternary Science Reviews 202, 109121.CrossRefGoogle Scholar
Langdon, J.S., 1987. Active osmoregulation in the Australian bass, Macquaria novemaculeata (Steindachner), and the golden perch, Macquaria ambigua (Richardson) (Percichthyidae). Marine and Freshwater Research 38, 771776.CrossRefGoogle Scholar
Leng, M.J., Lewis, J.P., 2014. Oxygen isotopes in molluscan shell: applications in environmental archaeology. Environmental Archaeology 21, 295306.CrossRefGoogle Scholar
Leng, M.J., Marshall, J.D., 2004. Palaeoclimate interpretation of stable isotope data from lake sediment archives. Quaternary Science Reviews 23, 811831.CrossRefGoogle Scholar
Lintermans, M., 2007. Fishes of the Murray-Darling Basin: An Introductory Guide. Murray-Darling Basin Commission, Canberra, Australia.Google Scholar
Long, K., Stern, N., Williams, I.S., Kinsley, L., Wood, R., Sporcic, K., Smith, T., et al. , 2014. Fish otolith geochemistry, environmental conditions and human occupation at Lake Mungo, Australia. Quaternary Science Reviews 88, 8295.CrossRefGoogle Scholar
Long, K., Wood, R., Williams, I.S., Kalish, J., Shawcross, W., Stern, N., Grün, R., 2018. Fish otolith microchemistry: snapshots of lake conditions during early human occupation of Lake Mungo, Australia. Quaternary International 463, 2943.CrossRefGoogle Scholar
Macdonald, J.I., Crook, D.A., 2010. Variability in Sr:Ca and Ba:Ca ratios in water and fish otoliths across an estuarine salinity gradient. Marine Ecology Progress Series 413, 147161.CrossRefGoogle Scholar
Magee, J.W.W., 1991. Late Quaternary lacustrine, groundwater, aeolian and pedogenic gypsum in the Prungle Lakes, southeastern Australia. Palaeogeography, Palaeoclimatology, Palaeoecology 84, 342.CrossRefGoogle Scholar
Mallen-Cooper, M., Stuart, I.G., 2003. Age, growth and non-flood recruitment of two potamodromous fishes in a large semi-arid/temperate river system. River Research and Applications 19, 697719.CrossRefGoogle Scholar
Mannino, M.A., Thomas, K.D., Leng, M.J., Sloane, H.J., 2008. Shell growth and oxygen isotopes in the topshell Osilinus turbinatus: resolving past inshore sea surface temperatures. Geo-Marine Letters 28, 309325.CrossRefGoogle Scholar
McTainsh, G.H., Lynch, A.W., 1996. Quantitative estimates of the effect of climate change on dust storm activity in Australia during the last glacial maximum. Geomorphology 17, 263271.CrossRefGoogle Scholar
Meredith, K.T., Hollins, S.E., Hughes, C.E., Cendón, D.I., Hankin, S., Stone, D.J.M., 2009. Temporal variation in stable isotopes (18O and 2H) and major ion concentrations within the Darling River between Bourke and Wilcannia due to variable flows, saline groundwater influx and evaporation. Journal of Hydrology 378, 313324.CrossRefGoogle Scholar
Olley, J.M., Roberts, R.G., Yoshida, H., Bowler, J.M., 2006. Single-grain optical dating of grave-infill associated with human burials at Lake Mungo, Australia. Quaternary Science Reviews 25, 24692474.CrossRefGoogle Scholar
Reeves, J.M., Barrows, T.T., Cohen, T.J., Kiem, A.S., Bostock, H.C., Fitzsimmons, K.E., Jansen, J.D., et al. , 2013. Climate variability over the last 35,000 years recorded in marine and terrestrial archives in the Australian region: an OZ-INTIMATE compilation. Quaternary Science Reviews 74, 2134.CrossRefGoogle Scholar
Rohling, E.J., 2016. Of lakes and fields: a framework for reconciling palaeoclimatic drought inferences with archaeological impacts. Journal of Archaeological Science 73, 1724.CrossRefGoogle Scholar
Simpson, H.J., Herczeg, A.L., 1991. Salinity and evaporation in the River Murray basin, Australia. Journal of Hydrology 124, 127.CrossRefGoogle Scholar
Skrzypek, G., Mydłowski, A., Dogramaci, S., Hedley, P., Gibson, J.J., Grierson, P.F., 2015. Estimation of evaporative loss based on the stable isotope composition of water using Hydrocalculator. Journal of Hydrology 523, 781789.CrossRefGoogle Scholar
Stern, N., 2015. The archaeology of the Willandra: its empirical structure and narrative potential. In: McGrath, A., Jebb, M.A. (Eds.), Long History, Deep Time: Deepening Histories of Place. ANU Press, Canberra, pp. 221240.Google Scholar
Stern, N., Tumney, J., Kajewski, P., 2013. Strategies for investigating human responses to changes in landscape and climate at Lake Mungo in the Willandra Lakes, southeast Australia. In: Frankel, D., Webb, J., Lawrence, S. (Eds.), Archaeology in Technology and Environment. Routledge, London, pp. 3150.Google Scholar
Stuart, I.G., 2006. Validation of otoliths for determining age of golden perch, a long-lived freshwater fish of Australia. North American Journal of Fisheries Management 26, 5255.CrossRefGoogle Scholar
Washburn, E.W., Urey, H.C., 1932. Concentration of the H2 isotope of hydrogen by the fractional electrolysis of water. Proceedings of the National Academy of Sciences 18, 496498.CrossRefGoogle Scholar
Weidman, C.R., Millner, R., 2000. High-resolution stable isotope records from North Atlantic cod. Fisheries Research 46, 327342.CrossRefGoogle Scholar
Ye, Q., Cheshire, K., Fleer, D., Centre, S.A.A.S., 2008. Recruitment of Golden Perch and Selected Large-Bodied Fish Species Following the Weir Pool Manipulation in the River Murray, South Australia. SARDI Research Report 303. SARDI Aquatic Sciences, Adelaide.Google Scholar
Zimmerman, C.E., 2005. Relationship of otolith strontium-to-calcium ratios and salinity: experimental validation for juvenile salmonids. Canadian Journal of Fisheries and Aquatic Sciences 62, 8897.CrossRefGoogle Scholar