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THE WATER RELATIONS AND IRRIGATION REQUIREMENTS OF SUGAR CANE (SACCHARUM OFFICINARUM): A REVIEW

Published online by Cambridge University Press:  26 January 2011

M. K. V. CARR*
Affiliation:
Cranfield University, Cranfield, Bedfordshire, MK43 0AL, UK
J. W. KNOX
Affiliation:
Cranfield University, Cranfield, Bedfordshire, MK43 0AL, UK
*
Corresponding author. [email protected]; Contact address: Pear Tree Cottage, Frog Lane, Ilmington, Shipston on Stour, Warwickshire, CV36 4LQ, UK

Summary

The results of research on the water relations and irrigation needs of sugar cane are collated and summarized in an attempt to link fundamental studies on crop physiology to irrigation practices. Background information on the centres of production of sugar cane is followed by reviews of (1) crop development, including roots; (2) plant water relations; (3) crop water requirements; (4) water productivity; (5) irrigation systems and (6) irrigation scheduling. The majority of the recent research published in the international literature has been conducted in Australia and southern Africa. Leaf/stem extension is a more sensitive indicator of the onset of water stress than stomatal conductance or photosynthesis. Possible mechanisms by which cultivars differ in their responses to drought have been described. Roots extend in depth at rates of 5–18 mm d−1 reaching maximum depths of > 4 m in ca. 300 d providing there are no physical restrictions. The Penman-Monteith equation and the USWB Class A pan both give good estimates of reference crop evapotranspiration (ETo). The corresponding values for the crop coefficient (Kc) are 0.4 (initial stage), 1.25 (peak season) and 0.75 (drying off phase). On an annual basis, the total water-use (ETc) is in the range 1100–1800 mm, with peak daily rates of 6–15 mm d−1. There is a linear relationship between cane/sucrose yields and actual evapotranspiration (ETc) over the season, with slopes of about 100 (cane) and 13 (sugar) kg (ha mm)−1 (but variable). Water stress during tillering need not result in a loss in yield because of compensatory growth on re-watering. Water can be withheld prior to harvest for periods of time up to the equivalent of twice the depth of available water in the root zone. As alternatives to traditional furrow irrigation, drag-line sprinklers and centre pivots have several advantages, such as allowing the application of small quantities of water at frequent intervals. Drip irrigation should only be contemplated when there are well-organized management systems in place. Methods for scheduling irrigation are summarized and the reasons for their limited uptake considered. In conclusion, the ‘drivers for change’, including the need for improved environmental protection, influencing technology choice if irrigated sugar cane production is to be sustainable are summarized.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2011

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References

REFERENCES

Allen, R. G., Pereira, L. S., Raes, D. and Smith, M. (1998). Crop evapotranspiration: guidelines for computing crop water requirements. Food and Agricultural Organisation of the United Nations, Irrigation and Drainage Paper 56, Rome, Italy.Google Scholar
Batchelor, C. R., Soopramanien, G. C., Bell, J. P., Nayamuth, R. and Hodnett, M. G. (1990). Importance of irrigation regime, dripline placement and row spacing in the drip irrigation of sugarcane. Agricultural Water Management 17:7594.CrossRefGoogle Scholar
Bell, J. P., Wellings, S. R., Hodnett, M. G. and Ah Koon, P. D. (1990). Soil water status: a concept for characterising soil water conditions beneath a drip irrigated row crop. Agricultural Water Management 17:171187.CrossRefGoogle Scholar
Bull, T. and Glasziou, K. T. (1976). Sugar cane. In Crop Physiology, 5172 (Ed. Evans, L. T.). Cambridge: Cambridge University Press.Google Scholar
Carr, M. K. V. (2001). The water relations and irrigation requirements of coffee. Experimental Agriculture 37:136.CrossRefGoogle Scholar
Carr, M. K. V. (2009). The water relations and irrigation requirements of banana (MUSA spp.). Experimental Agriculture 45:333371.Google Scholar
Chabot, R., Bouarfa, S., Zimmer, D., Chaumont, C. and Moreau, S. (2005). Evaluation of the sap flow determined with a heat balance method to measure the transpiration of a sugarcane canopy. Agricultural Water Management 75:1024.Google Scholar
Chang, Jen-hu, Campbell, R. B. and Robinson, F. E. (1963). On the relationship between water and sugar cane yield in Hawaii. Agronomy Journal 55:450453.Google Scholar
Cowan, I. R. and Innes, R. F. (1956). Meteorology, evaporation and the water requirements of sugar cane. Proceedings of the International Society of Sugar-cane Technologists 9:215232.Google Scholar
Dart, I. L., Baille, C. P. and Thorburn, P. J. (2000). Assessing nitrogen application rates for subsurface trickle irrigated sugarcane at Bundaberg. Procceedings of Australian Society of Sugarcane Technologists Conference. (Ed. Hogarth, D. M.) 22:230235.Google Scholar
Dodsworth, G. H., Nixon, D. J. and Sweet, C. P. M. (1990). An assessment of drip irrigation of sugarcane on poorly structured soils in Swaziland. Agricultural Water Management 17:325335.CrossRefGoogle Scholar
Donaldson, R. A. and Bezuidenhout, C. N. (2000). Determining the maximum drying off periods for sugarcane grown in different regions of the South African industry. Proceedings of the South African Sugar Technologists Association 74:162166.Google Scholar
Doorenbos, J. and Kassam, A. H. (1979). Yield response to water. Food and Agricultural Organization of the United Nations, Irrigation and Drainage Paper 33, Rome, Italy.Google Scholar
Ellis, R. D. and Lankford, B. A. (1990).The tolerance of sugarcane to water stress during the main development phases. Agricultural Water Management 17:117128.CrossRefGoogle Scholar
Ellis, R. D., Wilson, J. H. and Spies, P. M. (1985). Development of an irrigation policy to optimise sugar production during seasons of water shortage. Proceedings of the South African Sugar Technologists Association 59:142147.Google Scholar
Finkel, H. J. (1983). Irrigation of sugar crops. In CRC Handbook of Irrigation Technology, Volume II (Ed. Finkel, H. J.), Florida, USA, CRC Press.Google Scholar
George, B. R. F (1988). A simple field method of scheduling irrigation. Proceedings of the South African Sugar Technologists Association 149–151.Google Scholar
Glover, J. (1967). The simultaneous production of sugar cane roots and tops in relation to soil and climate. Proceedings of the South African Sugar Technology Association 41:143159.Google Scholar
Green, G., Sunding, D., Zilberman, D., and Parker, D. (1996). Explaining irrigation technology choices: a microparameter approach. American Journal of Agricultural Economics 78:10641072.Google Scholar
Gregory, P. J. (1990). Soil physics and irrigation: tapping the potential for drip. Agricultural Water Management 17:159169.Google Scholar
Haines, M. G., Inman-Bamber, N. G., Attard, S. J. and Linedale, A. I. (2010). Enhancing irrigation management planning with EnviroScan and WaterSense. http://www.irrigation.org.au/assets/pages/762A58E3-1708-51EB-A69E09D5747B3C06/82%20-%20Haines%20Paper.pdf [Accessed 24 October 2010].Google Scholar
Hobhouse, H. (1985). Seeds of Change: Five Plants that Transformed Mankind. London: Sidgwick and Jackson Ltd.Google Scholar
Hodnett, M. G., Bell, J. P., Al Koon, P. D.Soopramanten, G. C. and Batchelor, C. M. (1990). The control of drip irrigation of sugarcane using ‘index’ tensiometers, some comparisons with control by the water budget method. Agricultural Water Management 17:180207.Google Scholar
Holden, J. R. (1998). Irrigation of Sugarcane. Bureau of Sugar Experiment Stations, Brisbane, Australia.Google Scholar
Humbert, R. P. (1968). The Growing of Sugar Cane. Amsterdam: Elsevier.Google Scholar
ICSM (International Consortium for Sugarcane Modelling). (2008). http://sasri.sasa.org.za/misc/DSSAT%20Canegro%20SCIENTIFIC%20documentation_20081215.pdf [Accessed 24 October 2010].Google Scholar
Inman-Bamber, N. G. (1994). Temperature and seasonal effects on canopy development and light interception of sugarcane. Field Crops Research 36:4151.CrossRefGoogle Scholar
Inman-Bamber, N. G. (1995). Automatic plant extension measurement in sugarcane in relation to temperature and soil moisture. Field Crops Research 42:135142.Google Scholar
Inman-Bamber, N. G. (2004). Sugarcane water stress criteria for irrigation and drying off. Field Crops Research 89:107122.Google Scholar
Inman-Bamber, N. G., Attard, S. J., Haines, M. G. and Linedale, A. I. (2008). Deficit irrigation in sugarcane using the WaterSence scheduling tool. In Share the Water, Share the Benefits. Proceedings of the Irrigation Australia Congress, Melbourne, May 2008. http://www.irrigation.org.au/assets/pages/762A58E3-1708-51EB-A69E09D5747B3C06/79%20Inman%20Paper2.pdf [Accessed 24 October 2010].Google Scholar
Inman-Bamber, N. G., Bonnett, G. D., Spillman, M. F., Hewitt, M. L. and Xu, J. (2009). Source-sink differences in genotypes and water regimes influencing sucrose accumulation in sugarcane stalks. Crop and Pasture Science 60:316327.Google Scholar
Inman-Bamber, N. G. and De Jager, J. M. (1986). The reaction of two varieties of sugarcane to water stress. Field Crops Research 14:1528.CrossRefGoogle Scholar
Inman-Bamber, N. G. and McGlinchey, M. G. (2003). Crop coefficients and water-use estimates for sugarcane based on long-term Bowen ratio energy balance measurements. Field Crops Research 83:125138.Google Scholar
Inman-Bamber, N. G., Muchow, R. C. and Robertson, M. J. (2002). Dry matter partitioning of sugarcane in Australia and South Africa. Field Crops Research 76:7184.CrossRefGoogle Scholar
Inman-Bamber, N. G., Schuurs, M. and Muchow, R. C. (1999). Advances in the science and economics of supplementary irrigation of sugarcane. Proceedings of the South African Sugar Technologists Association 73:915.Google Scholar
Inman-Bamber, N. G. and Smith, D. M. (2005). Water relations in sugarcane and response to water deficits. Field Crops Research 92:185202.CrossRefGoogle Scholar
Inman-Bamber, N. G. and Spillman, N. F. (2002). Plant extension, soil water extraction and water stress in sugarcane. Proceedings of the Australian Society of Sugar Cane Technologists 24:242256.Google Scholar
James, G. (Ed.) (2004). Sugarcane. (2nd Edition). Oxford: Blackwell Publishing.Google Scholar
Jones, C. A., Santo, L. T., Kingston, G. and Gascho, G. J. (1990). Sugarcane. In Irrigation of Agricultural Crops (Eds. Stewart, B. A. and Nielsen, D. R.). Agronomy No. 30, Wisconsin, USA, American Society of Agronomy.Google Scholar
Julien, M. H. R., Irvine, J. E. and Benda, G. T. A. (1989). Sugarcane anatomy, morphology and physiology. In Diseases of Sugarcane (Eds. Ricaud, C., Egan, B. T., Gillaspie, A. G. Jr. and Hughes, C. G.). Amsterdam: Elsevier.Google Scholar
Kay, M. G. (1990). Recent developments for improving water management in surface and overhead irrigation. Agricultural Water Management 17:722.CrossRefGoogle Scholar
Knox, J. W., Rodríguez Díaz, J. A., Nixon, D., and Mkhwanazi, M. (2010). A preliminary assessment of climate change impacts on sugarcane in Swaziland. Agricultural Systems 103:6372.Google Scholar
Koehler, P. H., Moore, P. H., Jones, C. A., Dela Cruz, A. and Maretzki, A. (1982). Response of drip-irrigated sugarcane to drought stress. Agronomy Journal 74:906911.CrossRefGoogle Scholar
Laclau, P. B. and Laclau, J-P. (2009). Growth of the whole root system for a plant crop of sugarcane under rainfed and irrigated conditions in Brazil. Field Crops Research 114:351360.CrossRefGoogle Scholar
Lisson, S. N., Inman-Bamber, N. G., Robertson, M. J. and Keating, B. A. (2005). The historical and future contribution of crop physiology and modelling research to sugarcane production systems. Field Crops Research 92:321335.CrossRefGoogle Scholar
Liu, D. L., Kingston, G. and Bull, T. A. (1998). A new technique for determining the thermal parameters of phenological development in sugarcane, including suboptimum and supra-optimum temperature regimes. Agricultural and Forest Meteorology 90:119139.CrossRefGoogle Scholar
Martin, E. C., Stephens, W., Wiedenfeld, R., Bittenbender, H. C., Beasley, J. P. jr, Neibling, H., Gallian, J. J. and Moore, J. M. (2007). Sugar, Oil and Fibre. In Irrigation of Agricultural Crops (Eds Lascano, R. J. and Sojka, R. E.) Wisconsin: American Society of Agronomy.Google Scholar
Meinzer, F. C. and Grantz, D. A. (1989). Stomatal control of transpiration from a developing sugarcane canopy. Plant, Cell and Environment 12:635642.CrossRefGoogle Scholar
Merry, R. E. (2003). Dripping with success: the challenges of an irrigation redevelopment project. Irrigation and Drainage 52: 7183.Google Scholar
Meyer, W. S. (1997). The irrigation experience from Australia. In Intensive Sugarcane Production (Eds Keating, B. A. and Wilson, J. R.), 437454, Wallingford, UK: CAB International.Google Scholar
Mhlanga, B. F. N., Ndlovub, L. S. and Senzanje, A. (2006). Impacts of irrigation return flows on the quality of the receiving waters: A case of sugarcane irrigated fields at the Royal Swaziland Sugar Corporation (RSSC) in the Mbuluzi River Basin (Swaziland). Physics and Chemistry of the Earth 31:804813.CrossRefGoogle Scholar
Ng Kee Kwong, K. F., Paul, J. P. and Deville, J. (1999). Drip fertigation – a means for reducing fertiliser nitrogen to sugarcane. Experimental Agriculture 35:3137.Google Scholar
Nixon, D. J. and Workman, M. (1987). Drip irrigation of sugarcane on a poorly draining saline/sodic soil. In Proceedings of the South African Sugar Technologists Association, 140–145.Google Scholar
Olivier, F. and Singels, A. (2004). Survey of irrigation scheduling practices in the South African sugar industry. Proceedings of the South African Sugar Technologists Association 78:239243.Google Scholar
Omary, M. and Izuno, F. T. (1995). Evaluation of sugarcane evapotranspiration from water table data in the Everglades agricultural area. Agricultural Water Management 27:309319.Google Scholar
Pollok, J. G., Geldard, G. W. and Street, C. P. M. (1990). Experience with approximately 600 hectare drip irrigation at Simunye sugar estate, Swaziland. Agricultural Water Management 17:151158.Google Scholar
Portmann, F., Siebert, S., Bauer, C. and Döll, P. (2008). Global dataset of monthly growing areas of 26 irrigated crops: version 1.0. Frankfurt Hydrology Paper 6, Institute of Physical Geography, University of Frankfurt (Main), Germany.Google Scholar
Purseglove, J. W. (1972). Tropical Crops: Monocotyledons. London: Longman.Google Scholar
Qureshi, M. E.Wegener, M. K., Harrison, S. R. and Bristow, K. L. (2001). Economic evaluation of alternative irrigation systems for sugarcane in the Burdekin delta in north Queensland, Australia. In Water Resources Management, 4757 (Eds Brebbia, C. A., Anagnostopoulos, P., Katsifarakis, K. and Cheng, A. H-D.), Boston: WIT Press.Google Scholar
Roberts, J. M., Nayamuth, R. A., Batchelor, C. H. and Sooprramaten, G. C. (1990). Plant-water relations of sugarcane (Saccharum officinarum L.) under a range of irrigated treatments. Agricultural Water Management 17:95115.CrossRefGoogle Scholar
Robertson, M. J. and Donaldson, R. A. (1998). Changes in the components of cane and sucrose yield in response to drying-off of sugarcane before harvest. Field Crops Research 55:201208.Google Scholar
Robertson, M. J., Inman-Bamber, N. G. and Muchow, R. C. (1997). Opportunities for improving the use of limited water by the sugarcane crop. In Intensive Sugarcane Production, 287304, (Eds Keating, B. A. and Wilson, J. R.) Wallingford, UK: CAB International.Google Scholar
Robertson, M. J., Inman-Bamber, N. G., Muchow, R. C. and Wood, A. W. (1999). Physiology and productivity of sugarcane with early and mid-season water deficit. Field Crops Research 64:211227.Google Scholar
Robertson, M. J., Wood, A. W. and Muchow, R. C. (1996). Growth of sugar cane under high input conditions in tropical Australia. I. Radiation use, biomass accumulation and partitioning. Field Crops Research 48:1125.Google Scholar
SASA (1977). Irrigation of Sugarcane. Bulletin 17 (revised). The Experiment Station of the South African Sugar Association, Mount Edgecombe.Google Scholar
Simmonds, N. W. (1998). Tropical crops and their improvement. In Agriculture in the Tropics. 3rd edition. (Eds Webster, C. C. and Wilson, P. N.). Oxford: Blackwell Science.Google Scholar
Singels, A. and Smith, M. T. (2006). Provision of irrigation scheduling advice to small-scale sugarcane farmers using a web-based crop model and cellular technology: a South African case study. Irrigation and Drainage 55:363372.Google Scholar
Singels, A., van den Berg, M., Smit, M. A., Jones, M. R. and van Antwerpen, R. (2010). Modelling water uptake, growth and sucrose accumulation of sugarcane subjected to water stress. Field Crops Research 117:5969.Google Scholar
Smit, M. A. and Singels, A. (2006). The response of sugar cane canopy development to water stress. Field Crops Research 98:9197.Google Scholar
Smith, D. M., Inman-Bamber, N. G. and Thorburn, P. J. (2005). Growth and function of the sugarcane root system. Field Crops Research 92:169183.Google Scholar
Soopramanien, G. C. and Batchelor, C. R. (Eds) (1987). MSIRI-IH Drip Irrigation Research Project: Second Ratoon Crop Interim Report. Mauritius Sugar Industry Research Institute, Reduit, Mauritius.Google Scholar
Sumner, M. E. (1997). Opportunities for amelioration of soil physical and chemical constraints under intensive cropping. In Intensive Sugarcane Production, 305326, (Eds Keating, B. A. and Wilson, J. R.), Wallingford, UK: CAB International.Google Scholar
Teeluck, M. (1997). Development of the centre pivot irrigation system in Mauritius. http://www.gov.mu/portal/sites/ncb/moa/farc/amas97/html/p02.htm [Accessed 24 October 2010].Google Scholar
Thompson, G. D. (1976). Water use by sugarcane. Review paper No. 8. The South African Sugar Journal 60:593600, 627–635.Google Scholar
Thompson, G. D. and Boyce, J. P. (1967). Daily measurements of potential evapotranspiration from fully canopied sugarcane. Agricultural Meteorology 4:267279.Google Scholar
Thompson, G. D. and Boyce, J. P. (1971). Comparisons of measured evapotranspiration of sugarcane from large and small lysimeters. Proceedings of the South African Sugar Technologists Association 45:169176.Google Scholar
Thompson, G. D. and Boyce, J. P. (1972). Estimating water use by sugarcane from meteorological and crop parameters. Proceedings of the International Society of Sugar Cane Technologists 14:813826.Google Scholar
Thompson, G. D. and De Robillard, P. J. M. (1968). Water duty experiments with sugarcane on two soils in Natal. Experimental Agriculture 4:295310.Google Scholar
Thompson, G. D., Gosnell, J. M. and de Robillard, P. J. M. (1967). Resposes of sugarcane to supplementary irrigation on two soils in Natal. Experimental Agriculture 3:223238.Google Scholar
Thompson, G. D., Pearson, G. H. O. and Cleasby, T. G (1963).The estimation of the water requirements of sugarcane in Natal. Proceedings of the South African Sugar Technologists Association 37:134141.Google Scholar
Tilley, L. and Chapman, L. (1999). Benchmarking crop water index for the Queensland sugar industry. Bureau of Sugar Experiment Stations, Brisbane, Australia.Google Scholar
Torres, J. S. (1998). A simple visual aid for sugarcane irrigation scheduling. Agricultural Water Management 38:7783.CrossRefGoogle Scholar
Turner, N. C. (1990). Plant water relations and irrigation management. Agricultural Water Management 17:5973.CrossRefGoogle Scholar
Van Antwerpen, R. (1999). Sugar cane root growth and relationships to above ground biomass. Proceedings of the South African Sugar Technologists Association 73:8995.Google Scholar
Venkataramana, S., Gururaja Rao, P. N. and Naidu, K. M. (1986). The effects of water stress during the formative phase on stomatal resistance and leaf water potential and its relationship with yield in ten sugarcane varieties. Field Crops Research 13:345353.CrossRefGoogle Scholar
Wiedenfeld, R. P. (2000). Water stress during different sugarcane growth periods on yield and responses to N fertilisation. Agricultural Water Management 43:173182.CrossRefGoogle Scholar
Wiedenfeld, R. P. (2004). Scheduling water application on drip irrigated sugarcane. Agricultural Water Management 64:169181.Google Scholar
Wood, G. H. and Wood, R. A. (1967). The estimation of cane root development and distribution using radiophosphorous. Proceedings of the South African Sugar Technology Association 41:160168.Google Scholar
Yates, R. A. (1984). Sugar-cane as an irrigated crop. In Sugar Cane (Ed. Blackburn, F.), Longman.Google Scholar
Yates, R. A. and Taylor, R. D. (1986). Water use efficiencies in relation to sugarcane yields. Soil Use and Management 2:7076.Google Scholar
Zadrazil, H. (1990). Drag-line irrigation. Practical experience with sugarcane. Agricultural Water Management 17:2535.Google Scholar