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
Shopping Cart: ( empty )
You are here: Home > Journals > AN > EA04136
RESEARCH ARTICLE
Contents Vol 46(10)

Effect of raised beds, irrigation and nitrogen management on growth, water use and yield of rice in south-eastern Australia

H. G. Beecher A B E , B. W. Dunn A B , J. A. Thompson B C , E. Humphreys B D , S. K. Mathews A and J. Timsina D
+ Author Affiliations
- Author Affiliations

A NSW Department of Primary Industries, Yanco Agricultural Institute, PMB Yanco, NSW 2703, Australia.

B Cooperative Research Centre for Sustainable Rice Production, c/- Yanco Agricultural Institute, PMB Yanco, NSW 2703, Australia.

C NSW Department of Primary Industries, PO Box 736, Deniliquin, NSW 2710, Australia.

D CSIRO Land and Water, PMB 3, Griffith, NSW 2680, Australia.

E Corresponding author. Email: geoff.beecher@dpi.nsw.gov.au

Australian Journal of Experimental Agriculture 46(10) 1363-1372 https://doi.org/10.1071/EA04136
Submitted: 28 July 2004  Accepted: 22 July 2005   Published: 13 September 2006

Abstract

To remain economically and environmentally sustainable, Australian rice growers need to be able to readily respond to market opportunities and increase cropping system productivity and water productivity. Water availability is decreasing whereas its price is increasing. Alternative irrigation layouts and water management approaches could contribute to reduced water use and increased irrigation efficiency. This paper reports results for the first crop (rice) in a cropping system experiment to compare permanent raised bed and conventional layouts on a transitional red-brown earth at Coleambally, New South Wales. The performance of conventional ponded rice grown on a flat layout was compared with rice grown on 1.84-m wide, raised beds with furrow and subsurface drip irrigation. In addition, deep and shallow ponded water depth treatments (15 and 5 cm water depth over the beds) were imposed on the rice on beds during the reproductive period. A range of nitrogen (N) fertiliser rates (0–180 kg N/ha) was applied to all treatments. The traditional flat flooded treatment (Flat) achieved the highest grain yield of 12.7 t/ha, followed by the deep (Bed 15) and shallow (Bed 5) ponded beds (10.2 and 10.1 t/ha, respectively). The furrow (Furrow) irrigated bed treatment yielded 9.4 t/ha and the furrow/drip (Furr/Drip) treatment yielded the lowest grain yield (8.3 t/ha). Grain yield from all bed treatments was reduced owing to the wide furrows (0.8 m between edge rows on adjacent beds), which were not planted to rice. Rice crop water use was significantly different between the layout–irrigation treatments. The Flat, Bed 5 and Bed 15 treatments had similar input (irrigation + rainfall – surface drainage) water use (mean of 18.3 ML/ha). The water use for the Furrow treatment was 17.2 ML/ha and for the Furr/Drip treatment, 15.1 ML/ha. Input WP of the Flat treatment (0.68 t/ML) was higher than the raised bed treatments, which were all similar (mean 0.55 t/ML). This single season experiment shows that high yielding rice crops can be successfully grown on raised beds, but when beds are ponded after panicle initiation, there is no water saving compared with rice grown on a conventional flat layout. Preliminary recommendations for the growing of rice on raised beds are that the crop be grown as a flooded crop in a bankless channel layout. This assists with weed control and allows flooding for cold temperature protection, which is necessary with current varieties. Until we find effective herbicides and other methods of weed control and N application that do not require ponding, there is little scope for saving water while maintaining yield on suitable rice soil through the use of beds.

Additional keywords: permanent beds, subsurface drip, water productivity.


Acknowledgments

We thank Daniel Johnston for his considerable contribution during the course of the experiment, Brad Fawcett for assistance in installation of soil monitoring equipment and construction of circular flumes, and David Smith and Roy Zandona for weather data. Financial support for the project was provided by the Australian Centre for International Agricultural Research, Rural Industries Research and Development Corporation, Grains Research and Development Corporation and the CRC for Sustainable Rice Production. In kind contributions were provided by Coleambally Irrigation Cooperative Limited, Murray Irrigation Limited and Murrumbidgee Shire. We acknowledge the comments of Damian Heenan and Sam North on early drafts of this document.


References


Batten GD, Blakeney AB, Glennie-Holmes M, Henry RJ, McCaffery A, (1991) Rapid determination of shoot nitrogen status in rice using near infrared reflectance spectroscopy. Journal of the Science of Food and Agriculture 54, 191–197. open url image1

Beecher HG, Thompson JA, McCaffery DW, Muir JS (1997) Cropping on raised beds in southern NSW. NSW Agriculture, Agfact P1.2.1, Orange, NSW.

Beecher G, Beale P, Clampett WS (2000) Land for rice growing. In ‘Production of quality rice in south eastern Australia’. (Eds LM Kealy, WS Clampett) Chapter 4. (WS IREC: Griffith, NSW)

Beecher HG, Hume IH, Dunn BW (2002) Improved method for assessing rice soil suitability to restrict recharge. Australian Journal of Experimental Agriculture 42, 297–307.
Crossref | GoogleScholarGoogle Scholar | open url image1

Borrell AK, Garside AL, Fukai S (1997) Improving efficiency of water use for irrigated rice in a semi-arid tropical environment. Field Crops Research 52, 231–248.
Crossref | GoogleScholarGoogle Scholar | open url image1

Clemmens AJ, Bos MG, Replogle JA (1984) Portable RBC flumes for furrows and earthen channels. Transactions of the ASAE. American Society of Agricultural Engineers 21, 1016–1026. open url image1

Dunn BW, Williams RL, Beecher HG (1998) What’s happening with Amaroo rice nitrogen? IREC Farmers Newsletter, Large Area Edn No. 150, pp. 20–22.

Heenan DP, Thompson JA (1984) Growth, grain yield and water use of rice grown under restricted water supply in New South Wales. Australian Journal of Experimental Agriculture and Animal Husbandry 24, 104–109.
Crossref | GoogleScholarGoogle Scholar | open url image1

Humphreys E, Meyer WS, Prathapar SA, Smith DJ (1994) Estimation of evaporation from rice in southern New South Wales: a review. Australian Journal of Experimental Agriculture 34, 1069–1078.
Crossref | GoogleScholarGoogle Scholar | open url image1

Humphreys E, Bhuiyan M, Fattore A, Fawcett B, Smith DJ (2001) The benefits of winter crops after rice harvest. Part 1: Results of field experiments. IREC Farmers’ Newsletter, Large Area Edn No. 157, pp. 36–38.

Humphreys E, Muirhead WA, Lewin LG, Thompson JA, Stapper M, O’Keeffe KR, Beecher HG (2003) Increasing water use efficiency — rice-based cropping systems of southern NSW. Natural Resource Management, Special Issue June 2003, pp. 28–32.

Meyer WS (1999) Standard reference evaporation calculation for inland, south eastern Australia. CSIRO Land and Water, Technical report 35/98, Adelaide.

Muirhead WA, Humphreys E (Eds) (1984) ‘Rootzone limitations to crop production on clay soils. Symposium of the Australian society of soil science.’ (CSIRO Publishing: Melbourne)

Muirhead WA, Blackwell JB, Humphreys E, White RJG (1989) The growth and nitrogen economy of rice under sprinkler and flood irrigation in south-east Australia. I. Crop response and N uptake. Irrigation Science 10, 183–199.
Crossref | GoogleScholarGoogle Scholar | open url image1

Ockerby SE, Fukai S (2001) The management of rice grown on raised beds with continuous furrow irrigation. Field Crops Research 69, 215–226.
Crossref | GoogleScholarGoogle Scholar | open url image1

Ricecheck (2004) A guide to objective rice crop management for improving yields, grain quality and profits, and for economic and environmental sustainability. NSW Agriculture, Orange, NSW.

Samani Z, Jorat S, Yousaf M (1991) Hydraulic characteristics of circular flume. Journal of Irrigation and Drainage Engineering 117, 558–566. open url image1

Smith D, Humphreys E (2001) The benefits of winter crops after rice harvest. Part 2: Models to predict what will happen in your situation. IREC Farmers’ Newsletter Large Area Edn No. 157, pp.39–42.

Stannard ME (1970) Morphological description of soils occurring in Coleambally Irrigation Area. Water Conservation and Irrigation Commission, Sydney.

Thompson J, Griffin D, North S (2003) Improving the water use efficiency of rice. Co-operative research centre for sustainable rice production, Final report No. 1204, Yanco, NSW.

Turner AM, Lewin LG (1994) Establishment failure on NSW rice farms. In ‘Proceedings of the “Temperate rice — achievements and potential” conference’. (Eds E Humphreys, EA Murray, WS Clampett, LG Lewin) pp. 279–282. (Temperate Rice Conference Organising Committee, Yanco Agricultural Institute: Yanco, NSW)

Williams RL, Angus JF (1994) Deep floodwater protects high-nitrogen crops from low-temperature damage. Australian Journal of Experimental Agriculture 34, 927–932.
Crossref | GoogleScholarGoogle Scholar | open url image1