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Plant sciences, sustainable farming systems and food quality
RESEARCH ARTICLE

Improving water productivity in the Australian Grains industry—a nationally coordinated approach

J. A. Kirkegaard A B I , J. R. Hunt A B , T. M. McBeath A C , J. M. Lilley A B , A. Moore A B , K. Verburg A E , M. Robertson A D , Y. Oliver A D , P. R. Ward A D , S. Milroy D F and A. M. Whitbread G H
+ Author Affiliations
- Author Affiliations

A CSIRO Agriculture Flagship.

B CSIRO, GPO Box 1600, Canberra, ACT, 2601, Australia.

C CSIRO, PB 2 Glen Osmond, SA 5064, Australia.

D CSIRO, Private Bag 5, Wembley, WA, Australia.

E CSIRO Land and Water, GPO Box 1666, Canberra, ACT, 2601, Australia.

F Currently: Murdoch University, Murdoch, WA, 6150 Australia.

G Crop Production Systems in the Tropics, Georg-August-University, Gottingen, Grisebachstr. 6, D-37077, Gottingen, Germany.

H Currently: International Crop Research Institute for the Semi-Arid Tropics (ICRISAT), Patancheru, Andhra Pradesh 502 324, India.

I Corresponding author. Email: john.kirkegaard@csiro.au

Crop and Pasture Science 65(7) 583-601 https://doi.org/10.1071/CP14019
Submitted: 10 January 2014  Accepted: 5 June 2014   Published: 7 August 2014

Abstract

Improving the water-limited yield of dryland crops and farming systems has been an underpinning objective of research within the Australian grains industry since the concept was defined in the 1970s. Recent slowing in productivity growth has stimulated a search for new sources of improvement, but few previous research investments have been targeted on a national scale. In 2008, the Australian grains industry established the 5-year, AU$17.6 million, Water Use Efficiency (WUE) Initiative, which challenged growers and researchers to lift WUE of grain-based production systems by 10%. Sixteen regional grower research teams distributed across southern Australia (300–700 mm annual rainfall) proposed a range of agronomic management strategies to improve water-limited productivity. A coordinating project involving a team of agronomists, plant physiologists, soil scientists and system modellers was funded to provide consistent understanding and benchmarking of water-limited yield, experimental advice and assistance, integrating system science and modelling, and to play an integration and communication role. The 16 diverse regional project activities were organised into four themes related to the type of innovation pursued (integrating break-crops, managing summer fallows, managing in-season water-use, managing variable and constraining soils), and the important interactions between these at the farm-scale were explored and emphasised. At annual meetings, the teams compared the impacts of various management strategies across different regions, and the interactions from management combinations. Simulation studies provided predictions of both a priori outcomes that were tested experimentally and extrapolation of results across sites, seasons and up to the whole-farm scale. We demonstrated experimentally that potential exists to improve water productivity at paddock scale by levels well above the 10% target by better summer weed control (37–140%), inclusion of break crops (16–83%), earlier sowing of appropriate varieties (21–33%) and matching N supply to soil type (91% on deep sands). Capturing synergies from combinations of pre- and in-crop management could increase wheat yield at farm scale by 11–47%, and significant on-farm validation and adoption of some innovations has occurred during the Initiative. An ex post economic analysis of the Initiative estimated a benefit : cost ratio of 3.7 : 1, and an internal return on investment of 18.5%. We briefly review the structure and operation of the initiative and summarise some of the key strategies that emerged to improve WUE at paddock and farm-scale.

Additional keywords: drought, dryland farming, fallow, rotation, water-use efficiency, wheat.


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