Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Animal Production Science Animal Production Science Society
Food, fibre and pharmaceuticals from animals
REVIEW

No-tillage and conservation farming practices in grain growing areas of Queensland – a review of 40 years of development

G. A. Thomas A C , G. W. Titmarsh A , D. M. Freebairn A and B. J. Radford B
+ Author Affiliations
- Author Affiliations

A Agricultural Production Systems Research Unit, Queensland Department of Natural Resources and Water, PO Box 318, Toowoomba, Qld 4350, Australia.

B Queensland Department of Natural Resources and Water, Biloela Research Station, LMB 1, Biloela, Qld 4715, Australia.

C Corresponding author. Email: gregory.thomas@nrw.qld.gov.au

Australian Journal of Experimental Agriculture 47(8) 887-898 https://doi.org/10.1071/EA06204
Submitted: 1 July 2006  Accepted: 6 February 2007   Published: 16 July 2007

Abstract

Early agricultural practices in Queensland inadvertently led to accelerated soil erosion. During the 1940s, the Queensland Government initiated a soil conservation service that worked with the principles of matching land use with its capability, as well as runoff management using earth structures such as contour banks and grassed waterways. A concerted effort began in the 1960s to develop and adapt farming systems that maximised retention of crop residues to maintain surface cover to complement the earthworks. Investigation and promotion of farm machinery capable of dealing with high stubble levels commenced in the mid-1970s. Demonstrations of the benefits of reduced and no-tillage conservation farming practices for improved productivity and soil conservation also began at this time.

The combined research, development and extension efforts of farmers, grower organisations, agribusiness and government agencies have contributed to an increase in the understanding of soil–water–crop interactions that have led to the adoption of no-tillage and conservation farming practices in Queensland. In 2005, the overall area under no-tillage was ~50% of the cropping land in the main grain growing areas of southern and central Queensland, but was potentially as high as 85% among some groups of farmers. Conservation farming practices, in their many forms, are now regarded as standard practice, and the agricultural advisory industry is involved considerably in providing advice on optimum herbicide application and crop rotation strategies for these practices.

Factors hindering greater adoption of no-tillage include: farmer attitudes and aspirations, machinery conversion or replacement costs, buildup of soil and stubble-borne plant diseases, use of residual herbicides that may limit crop options, dual use of land for grazing and cropping, herbicide resistance, buildup of hard-to-kill weeds, the need for soil disturbance in some situations, and concerns by farmers about the effects of herbicides on the environment and human health.

Developments that may aid further adoption of no-tillage systems include: ongoing machinery modifications that allow greater flexibility in the cropping systems, refinement of controlled traffic farming and precision agriculture, improved crop resistance or tolerance to plant diseases associated with stubble retention, availability of more crop options and rotations, development of a broader spectrum of effective herbicides and the use of genetic modification technologies to breed herbicide-resistant crops.


References


ABARE (1999) AgAccess. (Australian Bureau of Agricultural and Resource Economics: Canberra)

ABS (2001) ‘Agricultural census – selected shire results 2000/01.’ (Australian Bureau of Statistics: Canberra)

Blacket D, Muller D (1990) ‘The benefits of zero tillage on crop production at ‘Arden Downs’, Bungunya, 1985–1989.’ (Queensland Department of Primary Industries)

Carberry PS, Hochman Z, McCown RL, Dalgliesh NP, Foale MA , et al. (2002) The FARMSCAPE approach to decision support: farmers’, advisers’, researchers’ monitoring, simulation, communication and performance evaluation. Agricultural Systems 74, 141–177.
Crossref | GoogleScholarGoogle Scholar | [Verified 1 May 2007]

McCown RL, Hammer GL, Hargreaves JNG, Holzworth D, Freebairn DM (1996) APSIM: A novel software system for model development, model testing, and simulation in agricultural systems research. Agricultural Systems 50, 255–271.
Crossref | GoogleScholarGoogle Scholar | [Verified 1 May 2007]

Radford B (2006) Twenty years of conservation cropping improves soil condition. The Conservation Farmer 6, 390–391. open url image1

Radford BJ, Nielsen RGH (1983) Extension of crop sowing time during dry weather by means of stubble mulching and water injection. Australian Journal of Experimental Agriculture and Animal Husbandry 23, 302–308.
Crossref | GoogleScholarGoogle Scholar | open url image1

Radford BJ, Carroll C, Lawrence P (1991) Why opportunity cropping? In ‘Opportunity cropping management – a profitable sustainable system’. (Eds J Daniels, J Chamberlain, A Garside) pp. 6–11. (Queensland Department of Primary Industries)

Radford BJ, Gibson G, Nielsen RGH, Butler DG, Smith GD, Orange DN (1992) Fallowing practices, soil water storage, plant-available soil nitrogen accumulation and wheat performance in south west Queensland. Soil and Tillage Research 22, 73–93.
Crossref | GoogleScholarGoogle Scholar | open url image1

Radford BJ, Thompson JP, Thomas GA (1993) Tillage and stubble management. In ‘Cropping strategies for the next decade – Queensland crop production conference proceedings 1992’. (Eds WM Strong, BJ Radford) pp. 149–162. (Queensland Department of Primary Industries).

Radford BJ, Key AJ, Robertson LN, Thomas GA (1995a) Conservation tillage increases soil water storage, soil animal populations, grain yield and response to fertiliser in the semi-arid sub-tropics. Australian Journal of Experimental Agriculture 35, 223–232.
Crossref | GoogleScholarGoogle Scholar | open url image1

Radford BJ, Thorburn PJ, Key AJ (1995b) Enhancement of wheat establishment with modified sowing and fallow management techniques. Soil and Tillage Research 36, 73–89.
Crossref | GoogleScholarGoogle Scholar | open url image1

Rawson JE, Bath SJ, Hazard WHL (1981) Effects of chemical and mechanical management of fallow land on soil moisture accumulation and yield of wheat. Queensland Journal of Agricultural and Animal Sciences 38, 195–202. open url image1

Ridley AM (2005) The role of farming systems group approaches in achieving sustainability in Australian agriculture. Australian Journal of Experimental Agriculture 45, 603–615.
Crossref | GoogleScholarGoogle Scholar | open url image1

Robinson JB (2005) Understanding and applying decision support systems in Australian farming systems research. PhD Thesis, University of Western Sydney.

Rowland P, Freebairn DM, Wockner GH, Hamilton NA, Silburn DM (1988) Fallow treatment effects on runoff, soil erosion, soil moisture and wheat yield on a brown clay soil in the Maranoa. In ‘Soil Management ’88 Symposium proceedings’. pp. 227–238. (Darling Downs Soil and Water Studies Centre, Darling Downs Institute of Advanced Education: Toowoomba, Qld)

Sallaway MM, Yule DF, Ladewig JH (1983) Effect of agricultural management on catchment runoff and soil loss in a semi arid tropical environment. In ‘Hydrology and water resources symposium’. pp. 252–256. (Institute of Engineers Australia: Hobart)

Sallaway MM, Lawson D, Yule DF (1988a) Ground cover during fallow from wheat, sorghum and sunflower stubble under three tillage practices in Central Queensland. Soil and Tillage Research 12, 347–364.
Crossref | GoogleScholarGoogle Scholar | open url image1

Sallaway MM, Yule DF, Lawson D, Carroll C, Fossett G, Burger P, Nickson D (1988b) Runoff and soil loss study, Capella, Central Queensland. Queensland Department of Primary Industries Project Report QO88012.

Sallaway MM, Yule DF, Mayer D, Burger PW (1990) Effects of surface management on the hydrology of a Vertisol in semi-arid Australia. Soil and Tillage Research 15, 227–245.
Crossref | GoogleScholarGoogle Scholar | open url image1

Scott JF, Farquharson RJ (2004) An assessment of the economic impacts of NSW Agriculture’s research and extension: conservation farming and reduced tillage in northern NSW. Economic Research Report No 19, NSW Department of Primary Industries, Tamworth, NSW.

Silburn DM, Freebairn DM (2004) Soil conservation in Australia’s semi arid tropics: pathways to success, and new challenges. In ‘Conserving soil and water for society: sharing solutions. Proceedings of the 13th International Soil Conservation Organisation conference’. (Eds SR Raine, AJW Biggs, NW Menzies, DM Freebairn, PE Tolmie) Paper No. 416. (CD-ROM) (Australian Society of Soil Science Incorporated/International Erosion Control Association)

Strong WM, Dalal RC, Weston EJ, Cooper JE, Lehane KJ, King AJ, Chicken CJ (1996) Sustaining productivity of a Vertisol at Warra, Queensland, with fertilisers, no-tillage or legumes. 2. Long-term fertiliser nitrogen needs to enhance wheat yields and grain protein. Australian Journal of Experimental Agriculture 36, 665–674.
Crossref | GoogleScholarGoogle Scholar | open url image1

Swartz GL (1969) Study tour of the United States and Canada, July to August, 1969. Queensland Department of Primary Industries.

Thomas GA, Standley J, Hunter HM, Blight GW, Webb AA (1990) Tillage and crop residue management affect Vertisol properties and grain sorghum growth over seven years in the semi-arid sub-tropics. 3. Crop growth, water use and nutrient balance. Soil and Tillage Research 18, 389–407.
Crossref | GoogleScholarGoogle Scholar | open url image1

Thomas GA, Gibson G, Nielsen RGH, Martin WD, Radford BJ (1995) Effects of tillage, stubble, gypsum, and nitrogen fertiliser on cereal cropping on a red-brown earth in south-west Queensland. Australian Journal of Experimental Agriculture 35, 997–1008.
Crossref | GoogleScholarGoogle Scholar | open url image1

Thomas GA, Felton WL, Radford BJ (1997) Tillage and crop residue management. In ‘Sustainable crop production in the sub-tropics: an Australian perspective’. (Eds AL Clarke, PB Wylie) pp. 195–213. (Queensland Department of Primary Industries)

Thomas GA, Thompson JP, Amos RN (2003) A long-term fallow management experiment on a Vertosol at Hermitage Research Station in southern Queensland, Australia. In ‘Soil management for sustainability. Proceedings of International Soil Tillage Research Organisation 16th triennial conference’. pp. 1223–1228.

Thompson JP (1990) Long-term nitrogen fertilisation of wheat and barley in the Hermitage tillage and stubble management trial. In ‘Proceedings of a workshop on long-term nitrogen fertilisation of crops. Queensland Department of Primary Industries Conference and Workshop Series QC90001’. (Eds I Vallis, GA Thomas) pp. 44–67. (Queensland Department of Primary Industries)

Thompson JP (1992a) Soil biotic and biochemical factors in a long-term tillage and stubble management experiment on a vertisol. 1. Seedling inhibition by stubble. Soil and Tillage Research 22, 323–337.
Crossref | GoogleScholarGoogle Scholar | open url image1

Thompson JP (1992b) Soil biotic and biochemical factors in a long-term tillage and stubble management experiment on a vertisol. 2. Nitrogen deficiency with zero tillage and stubble retention. Soil and Tillage Research 22, 339–361.
Crossref | GoogleScholarGoogle Scholar | open url image1

Thompson JP, Mackenzie J, Amos R (1995) Root-lesion nematode (Pratylenchus thornei) limits response of wheat but not barley to stored soil moisture in the Hermitage long-term tillage experiment. Australian Journal of Experimental Agriculture 35, 1049–1055.
Crossref | GoogleScholarGoogle Scholar | open url image1

Tod HH (1969) Stubble mulch farming and stubble mulch machinery in U.S.A. Report on study tour by Mr H. H. Tod (farmer) from ‘Poplar Farm’, Jondaryan, Queensland Department of Primary Industries.

Ward LD, Norris CP (1976) Conservation tillage systems in North America. A report on a study tour, July–August 1976. Part A. Division of Land Utilization, Queensland Department of Primary Industries.

Ward LD, Norris CP (1982) The development of ‘zero-till’ planting systems for heavy clay soils. In ‘Proceedings of the agricultural engineering conference. National conference publication no. 82/8’. pp. 189–196. (Institution of Engineers Australia)

Webb AA, Grundy MJ, Powell B, Littleboy M (1997) The Australian sub-tropical cereal belt: soils, climate and agriculture. In ‘Sustainable crop production in the sub-tropics: an Australian perspective. Queensland Department of Primary Industries Information Series QI97035’. (Eds AL Clarke, PB Wylie) pp. 8–23. (Queensland Department of Primary Industries)

Weston EJ, Lehane KJ, Christodoulou N, Thomas GA, King AJ, Orange DN, Holmes CJ, Dalal RC, Cawley ST (2001) Comparisons of conventional and zero tillage, 1996–1999. In ‘Western Farming Systems Project Results Booklet 2001’. pp. 47–50. (Queensland Government, Department of Primary Industries, Natural Resources and Mines)

Wischmeier WH, Smith DD (1978) Predicting rainfall-erosion losses – a guide to conservation planning. U.S. Department of Agriculture, Agric. Handbook. No. 537.

Wockner G, Freebairn D (1991) Water balance and erosion study on the eastern Darling Downs – an update. Australian Journal of Soil and Water Conservation 4, 41–47. open url image1

Wockner G, Dalgliesh N (2004) Monitoring and managing the ‘Soil Water Workshop’. In ‘Eastern Farming Systems Results Book 2004’. pp. 36–38. (Queensland Department of Primary Industries and Fisheries)

Wylie PB (1997) Practical and economic considerations. In ‘Sustainable crop production in the sub-tropics: an Australian perspective. Queensland Department of Primary Industries Information Series QI97035’. (Eds AL Clarke, PB Wylie) pp. 329–338. (Queensland Department of Primary Industries)

Wylie PB (2006) Zero-tillage 25 years on. In ‘Profitable farming’. p. 2. (Horizon Rural Management: Dalby, Qld)