Hostname: page-component-cd9895bd7-mkpzs Total loading time: 0 Render date: 2024-12-26T05:14:34.607Z Has data issue: false hasContentIssue false

Phytolith evidence for C4-dominated grassland since the early Holocene at Long Pocket, northeast Queensland, Australia

Published online by Cambridge University Press:  20 January 2017

Vanessa C. Thorn*
Affiliation:
Antarctic Research Center, Victoria University of Wellington, P.O. Box 600, Wellington, New Zealand
*
*Fax: +64-4-463-5186.E-mail address:vanessa.thorn@vuw.ac.nz.

Abstract

Preliminary phytolith analysis of ephemeral lake fill sediment at Long Pocket, near Toomba, northeast Queensland, Australia, indicates that a C4-dominated grassland with a minor woody component has been present in the region since ca. 8000 cal yr B.P. Based on the modern distribution of C4 and C3 native grasses in Australia, this suggests that mean summer temperatures of at least 14°C (ca. 10°C cooler than present) were maintained since the early Holocene. This interpretation is comparable with previous studies, which together imply that the establishment of C4-dominated grasses in central and northeast Australia occurred between the last glacial maximum (most likely after ca. 16,000 14C yr B.P.) and ca. 7200 14C yr B.P. (ca. 8000 cal yr B.P.). Taxonomic composition of the grassland appears relatively consistent since the early Holocene at Long Pocket and includes phytoliths comparable with those from modern Arundinoideae, Panicoideae, and Chloridoideae. Rare non-grass phytoliths are also present. A gradual decrease in abundance of saddle phytolith forms (attributed to Chloridoideae grasses) from the base of the record at ca. 6500–7000 cal yr B.P. suggests decreasing aridity throughout the Holocene. This trend could reflect a locally drawn out effect of the end of the postglacial arid period due to the well-drained basalt flow catchment maintaining a local arid habitat for the Chloridoideae grasses.

Type
Research Article
Copyright
University of Washington

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

Anonymous(1994). Climate of Townsville. Bureau of Meteorology, Townsville, Queensland., 10.Google Scholar
Boettinger, J.L., (1994). Biogenic opal as an indicator of mixing in an Alfisol/Vertisol landscape. Ringrose-Voase, A.J., Humphreys, G.S., Soil Micromorphology: Studies in Management and Genesis. Proceedings of the IX International Working Meeting on Soil Micromorphology. Developments in Soil Science Elsevier, Amsterdam/Shill, Townsville, Australia., 1726.Google Scholar
Bowdery, D., (1984). Phytoliths: a multitude of shapes. Unpublished BA(Hons) thesis, The Australian National University, .Google Scholar
Bowdery, D., (1996). Phytolith analysis applied to archeological sites in the Australian arid zone. Unpublished Ph.D. dissertation, The Australian National University, .Google Scholar
Bowdery, D., (1998). Phytolith Analysis applied to Pleistocene–Holocene Archeological Sites in the Australian Arid Zone. John Erica Hedges, Hadrian Books, Oxford, England.Google Scholar
Clark, R.L., East, T.J., Guppy, J., Johnston, A., Leaney, F., McBride, P., Wasson, R.J., (1992). Late Quaternary stratigraphy of the Magela Plain. Wasson, R.J., Modern Sedimentation and Late Quaternary Evolution of the Magela Creek Plain. Australian Government Publishing Service, Canberra., 2880.Google Scholar
Diester-Haass, L., Schrader, H.J., Thiede, J., (1973). Sedimentological and paleoclimatological investigations of two pelagic-ooze cores off Cape Barbas, Northwest Africa. Meteor Forschung-Ergebnisse. 16, 1966.Google Scholar
Ehleringer, J.R., Cerling, T.E., Helliker, B.R., (1997). C4 photosynthesis, atmospheric CO2, and climate. Oecologia. 112, 285299.CrossRefGoogle ScholarPubMed
Fredlund, G.G., Tieszen, L.T., (1994). Modern phytolith assemblages from the North American Great Plains. Journal of Biogeography. 21, 321335.Google Scholar
Fujiwara, H., Jones, R., Brockwell, S., (1985). Plant opals (phytoliths) in Kakadu archeological sites. Jones, R., Archeological Research in Kakadu National Park. Special Publication Australian National Parks and Wildlife Service, Canberra., 155169.Google Scholar
Hart, D.M., (1988). The plant opal content in the vegetation and sediment of a swamp at Oxford Falls, New South Wales, Australia. Australian Journal of Botany. 36, 159170.Google Scholar
Hart, D.M., (1990). Occurrence of the ‘Cyperaceae-type’ phytolith in dicotyledons. Australian Systematic Botany. 3, 745750.Google Scholar
Hattersley, P.W., (1983). The distribution of C3 and C4 grasses in Australia in relation to climate. Oecologia (Berlin). 57, 113128.Google Scholar
Hay, W.W., Soeding, E., DeConto, R.M., Wold, C.N., (2002). The Late Cenozoic uplift—climate change paradox. International Journal of Earth Science (Geologische Rundschau). 91, 746774.Google Scholar
Johnson, B.J., (1999). 65,000 years of vegetation change in Central Australia and the Australian summer monsoon. Science. 284, 11501152.Google Scholar
Kaplan, J.O., (2001). Modelling distributions of C3 and C4 plants during glacial/interglacial periods. Max Planck Institute for Biogeochemistry, Jena, Germany., Web-site: http://c3c4.utah.edu/snowbirdsymposium/abstras/Kaplan.htmlct. Access date 31/10/02.Google Scholar
Kealhofer, L., (1998). A combined pollen and phytolith record for fourteen thousand years of vegetation change in northeastern Thailand. Review of Palaeobotany and Palynology. 103, 8393.Google Scholar
Kershaw, A.P., (1976). A late Pleistocene and Holocene pollen diagram from Lynch's Crater, northeast Queensland, Australia. New Phytologist. 77, 469498.Google Scholar
Kershaw, A.P., (1979). Local pollen deposition in aquatic sediments on the Atherton Tableland, northeastern Queensland, Australia. Australian Journal of Ecology. 4, 253263.CrossRefGoogle Scholar
Kershaw, A.P., (1995). Environmental change in Greater Australia. Antiquity. 69, 656675.Google Scholar
Kershaw, A.P., Mackenzie, G.M., McMinn, A., (1993). Quaternary vegetation history of northeastern Queensland from pollen analysis of ODP Site 820. Proceedings of the Ocean Drilling Programme, Scientific Results. 133, 107114.Google Scholar
Kershaw, A.P., Nix, H.A., (1988). Quantitative palaeoclimatic estimates from pollen taxa using bioclimatic profiles of extant taxa. Journal of Biogeography. 15, 589602.Google Scholar
Kondo, R., Childs, C., Atkinson, I., (1994). Opal Phytoliths of New Zealand. Manaaki Whenua Press, Lincoln.Google Scholar
Longmore, M.E., (1997). Quaternary palynological records from perched lake sediments, Fraser Island, Queensland, Australia: rainforest, forest history and climatic control. Australian Journal of Botany. 45, 507526.Google Scholar
Metcalfe, C.R., (1960). Anatomy of the Monocotyledons. I. Gramineae. Clarendon Press, Oxford.Google Scholar
Miller, G.H., Magee, J.W., Jull, A.J.T., (1997). Low-latitude glacial cooling in the Southern Hemisphere from amino-acid racemization in emu eggshells. Nature. 385, 241244.Google Scholar
Moss, P.T., Kershaw, A.P., (2000). The last glacial cycle from the humid tropics of northeastern Australia: comparison of a terrestrial and a marine record. Palaeogeography, Palaeoclimatology, Palaeoecology. 155, 155177.Google Scholar
Mulholland, S.C., Rapp, G.J., (1992). A morphological classification of grass silica-bodies. Rapp, G. Jr., Mulholland, S.C., Phytolith Systematics: Emerging Issues. Advances in Archeological and Museum Science Plenum Press, New York., 6590.Google Scholar
Pack, S., Miller, G.H., Fogel, M.L., Spooner, N.A., (2003). Carbon isotopic evidence for increased aridity in northwestern Australia through the Quaternary. Quaternary Science Reviews. 22, 629643.Google Scholar
Pearsall, D.M., (2000). Paleoethnobotany—a Handbook of Procedures. Academic Press, San Diego.Google Scholar
Pearsall, D.M., Biddle, A., Chandler-Ezell, K., Collins, S., Stewart, S., Vientimilla, C., Zhijun Zhao, , Duncan, N.A., (1998). Phytoliths in the Flora of Ecuador: the University of Missouri Online Phytolith Database. Web-site: http://www.missouri.edu/~phyto/. Access date: 03/06/02.Google Scholar
Piperno, D.R., (1984). A comparison and differentiation of phytoliths from maize and wild grasses: use of morphological criteria. American Antiquity. 49, 361383.Google Scholar
Piperno, D.R., (1988). Phytolith Analysis, an Archeological and Geological Perspective. Academic Press, London.Google Scholar
Runge, F., (1996). Leaf Phytoliths and Silica Skeletons from East African Plants. Physical Geography. University of Päderborn, Germany., CD-ROM.Google Scholar
Scott, L., (2002). Grassland development under glacial and interglacial conditions in southern Africa: review of pollen, phytolith and isotope evidence. Palaeogeography, Palaeoclimatology, Palaeoecology. 177, 4757.Google Scholar
Simon, B.K., (1978). A Preliminary Check-List of Australian Grasses. Botany Branch, Department of Primary Industries, Brisbane., 88.Google Scholar
Stephenson, P.J., (2002). Age of a Holocene Diatom Sediment Lake fill Toomba North Queensland. Australian Institute of Nuclear Science and Engineering, Lucas Heights, New South Wales., Report 98/157R.Google Scholar
Stephenson, P.J., Burch-Johnston, A.T., Stanton, D., Whitehead, P.W., (1998). Three long lava flows in north Queensland. Journal of Geophysical Research. 103, 2735927370.Google Scholar
Stephenson, P.J., Polach, H., Wyatt, D.H., (1978). The age of the Toomba basalt, north Queensland. The Third Australian Geology Convention. Geological Society of Australia, Queensland Division, Brisbane.Google Scholar
Street-Perrott, F.A., (1994). Palaeo-perspectives: changes in terrestrial ecosystems. Ambio. 23, 3743.Google Scholar
Stuiver, M., Reimer, P.J., (1993). Extended 14C data base and revised CALIB 3.0 14C age calibration program. Radiocarbon. 35, 215230.Google Scholar
Theobald, W.L., Krahulik, J.L., Rollins, R.C., (1979). Trichome description and classification. Metcalfe, C.R., Chalk, L., Anatomy of the Dicotyledons. Clarendon Press, Oxford., 4053.Google Scholar
Twiss, P.C., (1992). Predicted world distribution of C3 and C4 grass phytoliths. Rapp, G. Jr., Mulholland, S.C., Phytolith Systematics—Emerging Issues. Plenum Press, New York., 113128.Google Scholar
van der Kaars, S.A., (1990). Late Quaternary vegetation and climate of Australasia as reflected by the palynology of eastern Indonesian deep sea piston cores. Unpublished Ph.D. dissertation, University of Amsterdam, .Google Scholar
van der Kaars, S.A., (1991). Palynology of eastern Indonesian marine piston cores: a late Quaternary vegetational and climatic record for Australasia. Palaeogeography, Palaeoclimatology, Palaeoecology. 85, 239302.Google Scholar
van der Kaars, S.A., Wang, X., Kershaw, P., Guichard, F., Setiabudi, D.A., (2000). A late Quaternary paleoecological record from the Banda Sea, Indonesia: patterns of vegetation, climate and biomass burning in Indonesia and northern Australia. Palaeogeography, Palaeoclimatology, Palaeoecology. 155, 135153.CrossRefGoogle Scholar
Wallis, L.A., (2000). Phytoliths, late Quaternary environment and archeology in tropical semi arid northwest Australia. Unpublished Ph.D. dissertation, The Australian National University, .Google Scholar
Wallis, L.A., (2001). Environmental history of northwest Australia based on phytolith analysis at Carpenter's Gap 1. Quaternary International. 82–85, 103117.Google Scholar
Watson, L., Dallwitz, M.J., (1992). The Grass Genera of the World. C.A.B. International, Wallingford.Google Scholar
Zeltich, I., (1987). Photorespiration. McGraw–Hill Encyclopedia of Science and Technology. McGraw–Hill, New York., 427430.Google Scholar