Register      Login
Crop and Pasture Science Crop and Pasture Science Society
Plant sciences, sustainable farming systems and food quality
RESEARCH ARTICLE

Tall wheat grass (Thinopyrum ponticum) and puccinellia (Puccinellia ciliata) may not be the answer for all saline sites: a case study from the Central Western Slopes of New South Wales

W. S. Semple A , P. M. Dowling B and T. B. Koen A C
+ Author Affiliations
- Author Affiliations

A Department of Environment and Climate Change, PO Box 445, Cowra, NSW 2794, Australia.

B Charles Sturt University, Faculty of Rural Management, PO Box 883, Orange, NSW 2800, Australia.

C Corresponding author. Email: Terry.Koen@environment.nsw.gov.au

Australian Journal of Agricultural Research 59(9) 814-823 https://doi.org/10.1071/AR07298
Submitted: 9 August 2007  Accepted: 12 June 2008   Published: 26 August 2008

Abstract

Emergence and survival of Thinopyrum ponticum cv. Dundas, Puccinellia ciliata cv. Meneman, and Trifolium fragiferum cv. Palestine were observed over three seasons (2004–06) on part of a salinised area in Central Western New South Wales. Grid sampling of topsoils in August 2003 indicated that the site was acidic (mean pHwater 6.05), sodic (exchangeable sodium percentage 29), and saline (estimated ECe 18 dS/m). The site comprised a mosaic of low-salinity (ECe ~6 dS/m) vegetated patches and high-salinity (ECe ~30 dS/m) bare patches where EC was highly variable seasonally (exceeding 100 dS/m) and spatially. Despite suboptimal rainfall, emergence of the grasses was satisfactory on bare patches in all seasons but T. fragiferum failed to emerge in 2004 and was omitted from subsequent sowings. Various methods of ‘engineering’ the bare patches, viz. ditching, mounding, straw mulching, liming, or hand weeding, failed to promote optimum growth of the grasses, although survival was generally enhanced in treatments that included a shallow ditch. Results of the experiments, and observations elsewhere on the salinised area (where some patches supported optimal performance of the three species), suggested that high salinity was the main reason for poor performance on the bare patches. It was concluded that comprehensive site definition, both spatial and temporal, is important before attempting revegetation. Nevertheless the response of T. ponticum and P. ciliata in ditches will be limited on high-salinity sites. In addition, it was observed that surface disturbance and reduced grazing promoted establishment and growth of pre-existing species, particularly Cynodon dactylon and Lolium rigidum. There are many salinised sites in the Central West of NSW where neither P. ciliata nor T. ponticum has performed well, nor would be expected to do so, and where management of native and naturalised species already present may provide the best option for enhancing ground cover and herbage production.

Additional keywords: optimal growth, salt-tolerance, variability, soil acidity, waterlogging.


Acknowledgments

The experiments were funded by the Sustainable Grazing for Saline Lands (SGSL) project and the NSW Departments of Primary Industries and Natural Resources (now Environment and Climate Change) on land provided by Richard and Rose McKay. Laboratory, field, and other assistance was provided by Kim Broadfoot, Geoff Millar, Madeleine Rankin, Phil Schultz, and Cassie Wesley. Warren King and Brian Murphy provided on-going advice, and Justin Hughes reviewed a draft of the manuscript. Thanks to you all.


References


Barrett-Lennard EG , Malcolm CV , Bathgate A (2003) ‘Saltland pastures in Australia: a practical guide.’ 2nd edn (Land, Water & Wool Sustainable Grazing on Saline Lands: Perth, W. Aust.)

Crosbie M (2006) Puccinellia proves its place. Salt Magazine 15, 8–9. open url image1

Crosbie RS , Hughes JD (2006) Challenging the paradigm: an example of anthropogenic modification to groundwater discharge causing a saline scald rather than an increase in recharge. In ‘10th Murray-Darling Basin Groundwater Workshop’. CD-ROM. (Murray-Darling Basin Commission: Canberra, ACT)

FitzGerald D , Fogarty P (1992) Species for saline soils on the Northern Tablelands. In ‘Proceedings 7th Annual Conference of Grassland Society of NSW’. pp. 91–92. (Grassland Society of NSW Inc.: Orange, NSW)

Fleck BC (1967) A note on the performance of Agropyron elongatum (Host.) Beauv. and Puccinellia (Parl.) sp. in revegetation of saline areas. Journal of the Soil Conservation Service of NSW 23, 261–269. open url image1

Harden GJ (Ed.) (1990–1993) ‘Flora of New South Wales. Vols 1–4.’ (NSW University Press: Kensington, NSW)

Hughes JD, Khan S, Crosbie RS, Helliwell S, Michalk DL (2007) Runoff and solute mobilisation processes in a semiarid headwater catchment. Water Resources Research 43, W09402.
Crossref | GoogleScholarGoogle Scholar | open url image1

Jeffrey SJ, Carter JO, Moodie KB, Beswick AR (2001) Using spatial interpolation to construct a comprehensive archive of Australian climatic data. Environmental Modelling & Software 16, 309–330.
Crossref | GoogleScholarGoogle Scholar | open url image1

Neil D, Richardson P (1990) A sediment and nutrient budget for a seepage scald on the Southern Tablelands of New South Wales. Australian Journal of Soil and Water Conservation 3(2), 44–49. open url image1

Northcote KH (1971) ‘A factual key for the recognition of Australian soils.’ (Rellim Technical Publications: Adelaide, S. Aust.)

Rayment GR , Higginson FR (1992) ‘Australian laboratory handbook of soil and water chemical methods.’ (Inkata Press: Melbourne, Vic.)

Semple WS, Cole IA, Koen TB (2003) Performance of some perennial grasses on severely salinised sites of the inland slopes of New South Wales. Australian Journal of Experimental Agriculture 43, 357–371.
Crossref | GoogleScholarGoogle Scholar | open url image1

Semple WS, Cole IA, Koen TB, Costello D, Stringer D (2006a) Native couch grasses for revegetating severely salinised sites on the inland slopes of NSW. Part 2. The Rangeland Journal 28, 163–173.
Crossref | GoogleScholarGoogle Scholar | open url image1

Semple WS, Koen TB (2002) Revegetating saline seepage scalds: effectiveness of fencing. Natural Resource Management 5(2), 31–34. open url image1

Semple WS, Koen TB, Eldridge DJ, Düttmer K, Parker B (2006b) Variation in soil properties on two partially revegetated saline scalds in south eastern Australia. Australian Journal of Experimental Agriculture 46, 1279–1289.
Crossref | GoogleScholarGoogle Scholar | open url image1

Semple WS , Koen TB , Williams BG , Murphy BW , Nicholson AT (1996) Saline seepage scalds in the Central West of NSW. Technical Report 29, Department of Land and Water Conservation, Sydney, NSW.

Slavich PG, Petterson GH (1993) Estimating the electrical conductivity of saturated paste extracts from 1 : 5 soil : water suspensions and texture. Australian Journal of Soil Research 31, 73–81.
Crossref | GoogleScholarGoogle Scholar | open url image1

Southwell A (1999) Productive management of saline soil. In ‘Proceedings 14th Annual Conference Grassland Society NSW’. pp. 73–77. (Grassland Society of NSW Inc.: Orange, NSW)

Teakle LJH, Burvill GH (1945) The management of salt lands in Western Australia. Journal of the Department of Agriculture of Western Australia (Second Series) 22, 87–92. open url image1

Williams BG , Bullock PR (1989) The classification of salt-affected land in Australia. Technical Memorandum 89/8, CSIRO Division of Water Resources, Canberra, ACT.

Yunusa IAM, Newton PJ (2003) Plants for amelioration of subsoil constraints and hydrological control: the primer-plant concept. Plant and Soil 257, 261–281.
Crossref | GoogleScholarGoogle Scholar | open url image1









*Except where indicated, botanic nomenclature follows that of Harden (1990–1993).