Modelling vegetation health from the interaction of saline groundwater and flooding on the Chowilla floodplain, South Australia
I. C. Overton A C D , I. D. Jolly A , P. G. Slavich B , M. M. Lewis C and G. R. Walker AA CSIRO Division of Land and Water, Urrbrae, SA 5064, Australia.
B Wollongbar Agricultural Institute, NSW Agriculture, Wollongbar, NSW 2477, Australia.
C University of Adelaide, Department of Soil and Water, Urrbrae, SA 5064, Australia.
D Corresponding author. Email: ian.overton@csiro.au
Australian Journal of Botany 54(2) 207-220 https://doi.org/10.1071/BT05020
Submitted: 10 February 2005 Accepted: 20 October 2005 Published:
Abstract
The native riparian vegetation communities on the Chowilla floodplain in the lower River Murray in South Australia are suffering severe declines in health, particularly the Eucalyptus camaldulensis Dehnh. (red gum) and Eucalyptus largiflorens F.Muell. (black box) communities. The primary cause of the decline is salinisation of the floodplain soils caused by increased rates of groundwater discharge and hence increased movement of salt up into the plant root zone. The salinity is driven by a lack of flooding and rising saline groundwater tables. Rises in the naturally saline groundwater levels are due to the effects of river regulation from Lock 6 and high inflows from regional groundwater levels increased by Lake Victoria to the east. River regulation has also led to reduced frequency and duration of the floods that leach salt from the plant root zone and supply fresh water for transpiration. The frequency of medium-sized floods occurring on Chowilla has been reduced by a factor of three since locking and water extractions were commenced in the 1920s to provide reliable water for urban and agricultural use. The soil salinisation on the floodplain was modelled by using a spatial and temporal model of salt accumulation from groundwater depth, groundwater salinity, soil type and flooding frequency. The derived soil water availability index (WINDS) is used to infer vegetation health and was calibrated against current extent of vegetation health as assessed from fieldwork and satellite image analysis. The modelling work has shown that there is a severe risk to the floodplain vegetation from current flow regimes. This paper estimates that 65% (5658 ha) of the 8600 ha of floodplain trees are affected by soil salinisation matching a field survey of vegetation health in 2003 (Department of Environment and Heritage 2005a), compared with 40% in 1993 (Taylor et al. 1996). Model results show that the best management option for Chowilla is lowering the groundwater down to 2 m below current levels, which predicts an improvement in the health of the floodplain tree species from 35 to 42%.
Akeroyd MD,
Tyerman SD,
Walker GR, Jolly ID
(1998) Impact of flooding on the water use of semi-arid riparian eucalypts. Journal of Hydrology 206, 104–117.
| Crossref | GoogleScholarGoogle Scholar |
Barnett SA and South Australian Department of Mines and Energy (1991). Renmark hydrogeological map (1 : 250 000 scale). (Bureau of Mineral Resources, Geology and Geophysics: Canberra)
Collingham, EB (1990). The influence of hydrogeologic processes on soil salinity in the Chowilla anabranch. South Australian Engineering and Water Supply Department Technical Discussion Paper : Adelaide)
Dawes WR, Slavich PG, Hatton TJ, Walker GR
(1998) Modelling water and salt movement on the Chowilla floodplain. In ‘WAVES: an Integrated Energy and Water Balance Model’. , Canberra.
Department of Environment and Heritage
(2005)
Department of Environment and Heritage
(2005)
Department of Sustainable Natural Resources (2003).
Eldridge SR, Thorburn PJ, McEwan KL, Hatton TJ
(1993)
Gippel C, Blackham D
(2002) Review of environmental impacts of flow regulation and other water resource developments in the River Murray and Lower Darling River System. Report prepared for the Murray Darling Basin Commission by Fluvial Systems Pty Ltd.
Hodgson G
(1993) Predicting the health of Eucalyptus largiflorens in the Chowilla Anabranch Region of the Murray River using GIS and remote sensing. BSc(Honours) Thesis
(Resource and Environmental Management, Australian National University:
Canberra)
Hollingsworth ID
(1990) A reconnaissance soil survey of the Chowilla Anabranch System of the River Murray in South Australia and New South Wales. Report prepared for Murray–Darling Basin Commission by the Loxton Research Centre South Australian Department of Agriculture, Adelaide.
Jolly ID, Walker GR
(1996) Is the field water use of Eucalyptus largiflorens F.Muell. affected by short-term flooding? Australian Journal of Ecology 21, 173–183.
Jolly, ID ,
McEwan, KL ,
Holub, AN ,
Walker, GR ,
Dighton, JC ,
and
Thorburn, PJ (1992a). Compilation of groundwater data from the Chowilla Anabranch Region, South Australia. CSIRO Division of Water Resources Technical Memorandum No. 92/9 a. : Canberra, Australia)
Jolly, ID ,
Walker, GR ,
Thorburn, PJ ,
and
Hollingsworth, ID (1992b). The cause of black box decline in the Chowilla Anabranch Region, South Australia, and possible ameliorative approaches. In ‘Proceedings of national conference on vegetation and water management, Adelaide’. b. pp. 33–41. : Greening Australia, Canberra)
Jolly ID, Walker GR, Narayan KA
(1993) Floodwater/aquifer interaction in an arid floodplain and its implications for River Murray salinity. In ‘Proceedings of hydrology and water resources symposium, Newcastle, Australia’.
Jolly ID,
Walker GR, Thorburn PJ
(1993b) Salt accumulation in semi-arid floodplain soils with implications for forest health. Journal of Hydrology 150, 589–614.
| Crossref | GoogleScholarGoogle Scholar |
Jolly ID,
Walker GR, Narayan KA
(1994) Floodwater recharge processes in the Chowilla Anabranch system. Australian Journal of Soil Research 32, 417–435.
| Crossref | GoogleScholarGoogle Scholar |
Jurskis V
(2005) Eucalypt decline in Australia, and a general concept of tree decline and dieback. Forest Ecology and Management 215, 1–20.
| Crossref | GoogleScholarGoogle Scholar |
Margules and Partners, P. and J. Smith Ecological Consultants, Victorian Department of Conservation, Forests and Lands (1990).
Mensforth LJ,
Thorburn PJ,
Tyerman SD, Walker GR
(1994) Sources of water used by riparian Eucalyptus camaldulensis overlying highly saline groundwater. Oecologia 100, 21–28.
| Crossref | GoogleScholarGoogle Scholar |
Murray Darling Basin Commission
(2003) Preliminary investigations into observed river red gum decline along the River Murray below Euston. , Canberra.
Noyce, T ,
and
Nicolson, K (1993).
Ohlmeyer RG
(1991)
Overton IC
(2005) Modelling floodplain inundation on a regulated river: integrating GIS, remote sensing and hydrological models. River Research and Applications 21, 991–1001.
| Crossref | GoogleScholarGoogle Scholar |
Overton IC, Jolly ID
(2004) Integrated studies of floodplain vegetation health, saline groundwater and flooding on the Chowilla floodplain, South Australia. CSIRO Land and Water Technical Report No. 20/04 , Canberra.
Overton, IC ,
Walker, GR ,
and
Jolly, ID (1995). Modelling soil salinisation risk on a River Murray floodplain using a geographical information system—Chowilla, South Australia. In ‘AURISA ‘95: proceedings of the Australasian Urban and Regional Information Systems Association, Melbourne’. pp. 197–210.
Overton, IC ,
Slavich, PG ,
Jolly, ID ,
and
Walker, GR (1997). Modelling soil salinisation and vegetation health of a River Murray floodplain over time. In ‘Proceedings of the international congress on modelling and simulation MODSIM ’97’, Hobart.
Overton, IC ,
Newman, B ,
Erdmann, B ,
Sykora, N ,
and
Slegers, S (1999). Modelling floodplain inundation under natural and regulated flows in the lower River Murray. In ‘Proceedings of the second Australian stream management conference, Adelaide’.
Sharley T, Huggan C
(1995)
Slavich PG,
Walker GR, Jolly ID
(1999a) A flood history weighted index of average root-zone salinity for assessing flood impacts on health of vegetation on a saline floodplain. Agricultural Water Management 39, 135–151.
| Crossref | GoogleScholarGoogle Scholar |
Slavich PG,
Walker GR,
Jolly ID,
Hatton TJ, Dawes WR
(1999b) Dynamics of Eucalyptus largiflorens growth and water use in response to modified watertable and flooding regimes on a saline floodplain. Agricultural Water Management 39, 245–264.
| Crossref | GoogleScholarGoogle Scholar |
Smith M
(1989) Environmental management issues in the Chowilla region. In ‘Conservation in management of the River Murray system—making conservation count’. Proceedings of the third Fenner conference on the environment, Canberra, September 1989.
Taylor PJ,
Walker GR,
Hodgson G,
Hatton TJ, Correll RL
(1996) Testing of a GIS model of Eucalyptus largiflorens health on a semi-arid, saline floodplain. Environmental Management 20, 553–564.
| Crossref | GoogleScholarGoogle Scholar | PubMed |
Thorburn PJ
(1993) Groundwater uptake by Eucalyptus forests on the Chowilla floodplain, South Australia: implications for groundwater hydrology and forest ecology and health. PhD Thesis
(Flinders University of South Australia:
Adelaide)
Thorburn PJ,
Walker GR, Jolly ID
(1995) Uptake of saline groundwater by plants: an analytical model for semi-arid and arid areas. Plant and Soil 175, 1–11.
Warrick AW
(1988) Additional solutions for steady-state evaporation from a shallow water table. Soil Science 1988, 63–66.
Yan, W ,
Marsden, Z ,
and
Howles, S (2005).
Zubrinich TM,
Loveys B,
Gallasch S,
Seekamp JV, Tyerman SD
(2000) Tolerance of salinised floodplain conditions in a naturally occurring Eucalyptus hybrid related to lowered plant water potential. Tree Physiology 20, 953–963.
| PubMed |