Abstract
Water supply is a major constraint to crop production particularly for grain legumes more than 80% of which are grown under rainfed conditions. Global warming is increasing the problem by creating serious water shortages and large inter-seasonal fluctuations. Water use efficiency (WUE) provides a quick and simple measure of how well rain or irrigation water can be converted into grain. It represents a given level of biomass or grain yield per unit of water used by the crop. Improving crop productivity therefore requires answering the following question. How can WUE be improved and how can cropping systems be modified to result in a more efficient use of water?
A review of the literature reveals a large variation in WUE across a range of climate, soils and crops. Typically low and unstable yields of grain legumes are due to receding soil moisture at the time of sowing and terminal drought. Numerous studies have shown that grain yield is positively correlated with post-flowering water use. The actual crop water requirement usually varies with genotype, its growing duration and agronomic and soil management methods used. Differences in water requirements are mainly due to differences in canopy structure, root system and growth periods. Water stress adversely affects biological nitrogen fixation, plant growth, grain yield and WUE. Crop adaptation to drought is a function of the interaction of phenology with the pattern of water use. Plant architecture and root systems play a key role in the use of available soil moisture. Development of early flowering and pod set, rapid seed fill and early maturity varieties seems to be quite advantageous for increasing drought tolerance and improving WUE. It is possible to increase WUE, by 25–40% through soil management that involves deep tillage, crop residues, mulches, etc. Among agronomic practice options for increasing WUE, various experiments reveal about 12% increase in WUE associated with timely sowing. Supplemental irrigation at the reproductive phase may result in approximately 75% increase in grain yield and 35% increase in WUE. The drilling of phosphorus and zinc in deficient soils gives substantially higher grain yields and enhances water use. Conservation practices associated with harvesting the maximum amount of rain water and a watershed based water-harvesting and recycling system may be established on a large scale for providing life-saving irrigation. Sprinkling irrigation, drip irrigation or film hole irrigation practices save more than 50% water and increase the grain yield significantly. However, these advanced and costly techniques have very limited scope in grain legumes due to their low yields. Improved technology such as land leveling, crop rotation, intercropping, integrated use of farm resources and timely socio-economic interventions can help greatly in improving crop productivity and water use of cool season grain legumes.
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References
J.K. Aase and J.L. Pikul, Jr. (1995). Crop and soil response to long-term no-tillage practices in the northern Great Plains. Agron J 87, 652–656.
M.C. Agarwal, A.S. Dhaliwal, C.S. Jaiswal, A. Parbhakar, and M.S. Ahujla (1997). Status of research on agricultural water management of northern region. AICRP on Water Management. Directorate of Water Management Research, ICAR, Patna, p. 138.
I.P.S. Ahlawat and D.S. Rana (2002). Agronomic practices and crop productivity. In: Singh, G., Sekhon, H.S., Kolar, J.S. (eds.), Recent advances in agronomy, pp. 313–340. Indian Society of Agronomy, New Delhi.
M.M. Anders, M.V. Potdar, and C.A. Franchis (1996). Significance of intercropping in cropping systems. In: Ito, O., Johansen, C., Adugyamphi, J.J., Katayama, K., Kumar Rao, J.V.D.K. and Regot, J., (eds.), Roots and nitrogen in cropping systems of the semi-arid tropics, pp. 1–18. ICRISAT, Patancheru, Andhra Pradesh.
P.S. Basu and D.N. Singh (2003). Physiology and abiotic stresses in chickpea. In: Ali, M., Kumar, S., Singh, N.B. (eds.), Chickpea research in India, pp. 137–166. Indian Institute of Pulses Research, Kanpur.
V.O. Biederbeck and O.T. Bouman (1994). Water use by annual green manure legumes in dryland cropping systems. Agron J 86, 543–549.
A. Blum (1988). Plant breeding for stress environments. CRC Press, Boca Raton, FL.
R.L. Burns, D.J. Cook, and R.E. Phillips (1971). Influence of no-tillage on soil moisture. Agron J 73, 593–596.
I. Cakmak (2000). Possible roles of zinc in protecting plant cells from damage by reactive oxygen species. New Phytol 146, 185–205.
K.Y. Chan and D.P. Heenan (1993). Surface hydraulic properties of a real earth under continuous cropping with different management practices. Aust J Soil Res 31, 13–24.
B.T. Chandrakar, B.R. Chandravansi, and S.K. Taunk (1991). Effect of irrigation methods on yield potential of chickpea (Cicer arietinum L.) in a rice (Oryza sativa) based cropping system. Indian J Agron 36(Suppl.), 1–4.
A.G. Condon and A.G. Richards (1993). Exploiting genetic variation in transpiration efficiency in wheat: An agronomic view. In: Ehleringer, J.R., Hall, A.E., Ferguhar, G.D. (eds.), Stable isotopes and plant carbon – Water relations, pp. 435–450. Academic Press, San Diego, CA.
A.G. Condon, R.A. Richards, G.J. Rebetzke, and G.D. Farquhar (2004). Breeding for high water-use efficiency. J Exp Bot Water-Saving Special Issue 55(407), 2447–2450.
H.P. Cresswell, D.J. Painter, and K.C. Cameron (1993). Tillage and water content effects on surface soil hydraulic properties and shortwave albedo. Soil Sci Soc Am J 57, 816–824.
D.V. Deshmukh, L.B. Mhase, and B.M. Jamdagni (2004). Evaluation of chickpea genotypes for drought tolerance. Indian J Pulses Res 17, 47–49.
C.T. deWit (1958). Transpiration and crop yields. Versl. Landouwk. Onderz 64-6. Institute of Biology and Chemical Research on Field Crops and Herbage, Wageningen, The Netherlands.
L. Fu (1989). Developing status and prospects of micro-irrigation technology in China. Proceedings of Symposium of Water-Saving Agriculture and Development on Technology of Irrigation and Drainage in China, Institute of Field Irrigation of Chinese Academy of Agricultural Sciences, pp. 51–55.
A.E. Gallacher and J.I. Sprent (1978). The effect of different water regimes on growth and development of green house growth of V. faba. J Exp Bot 28, 412–423.
B.W. Greb (1966). Effect of surface-applied wheat straw on soil water losses by solar distillation. Soil Sci Soc Am Proc 30, 786–788.
A. Hamdy, E. Regab, and E. Scarascia-Mugnozza (2003). Coping with water scarcity, water saving and increasing water productivity. Irrig Drain 52, 3–20.
J.L. Hatfield, T.J. Saver, and J.H. Prueger (2001). Managing soils to achieve greater water use efficiency: A Review . Agron J 93, 271–280.
M.C. Heath and P.D. Hebblethwaite (1985). Solar radiation interception of leafless, semi-leafless peas (Pisum sativum) under contrasting field conditions. Ann Appl Biol 107, 300–318.
R.L. Hill (1990). Long-term conventional and no-till effects on selected soil physical properties. Soil Sci Soc Am J 54, 161–166.
T.C. Hsiao (1973). Plant responses to water stress. Annu Rev Plant Physiol 24, 519–570.
T.C. Hsiao, J.C. O’Toole, E.B. Yambaso, and N.C. Turner (1984). Influence of osmotic adjustment on leaf rolling and tissue death in rice (Oryza sativa L.). Plant Physiol 95, 338–341.
G. Hughes and J.D.H. Keatinge (1983). Solar radiation interception, dry matter production and yield in pigeonpea {Cajanus cajan (L.) Millspaugh}. Field Crops Res 6, 171–178.
ICRISAT (1993). Chickpea. Legumes Program Annual Report, 1992. Patancheru, Andhra Pradesh, pp. 15–53.
D. Jia (1999). Issues of agricultural water saving in yellow river basin. Irrig Drain 18(3), 1–3.
D. Jia, T. Si, and H. Wang (1994). Study on sustainable development of water-saving agriculture. Ecol Agric Study 2(2), 30–36.
M.R. Johansooz (1999). Wheat-chickpea yield performance, competition and resource use in intercropping under rainfed conditions of South Australia. Ph.D. Thesis, University of Adelade.
M. Kacemi (1992). Water conservation, crop rotations and tillage systems in semiarid Morocco. Ph.D. Dissertation, Colorado State University, Fort Collins, Colorado, USA.
H.R. Khan, G.K. McDonald, and Z. Rangel (2003). Zn fertilization improves water use efficiency, grain yield and seed Zn content in chickpea. Plant Soil 249(2), 389–400.
R. Khanna-Chopra and S.K. Sinha (1987). Chickpea physiological aspects of growth and yield. In: Saxena, M.C. and Singh, K.B. (eds.), The chickpea, pp. 163–190. CAB International, Wallingford.
L. Krishnamurthi, J. Kashiwagi, H.D. Upadhyaya, and R. Serraj (2003). Genetic diversity of drought avoidance root traits in the mini-core germplasm collection of chickpea. Int Chickpea Pigeonpea Newsl 10, 21–28.
X. Lin and L. Zhao (1999). Water saving technology for surface irrigation of dry land crops. China Water Power Press, Beijing.
C. Liu and L. Li (1999). Suitable water supply and water-saving industrial engineering in China. Problems on Water Saving Agriculture in China (Department of Rural and Social Development, Ministry of Science and Technology, China). China Water Power Press, Beijing, pp. 42–57.
M.M. Ludlow and R.C. Muchow (1990). A critical evaluation of traits for improving crop yields in water-limited environments. Adv Agron 43, 107–153.
D.K. Malinda and R. Darling 2002. Amelioration of compacted sub-soil layer by tillage rotation and its effect on productivity. Proceedings of the 17th World Congress on Soil Science, Bangkok. August 2002, pp. 23-1–23-13.
R. Monica, L. Consortium, and L. Consortium (2007). Breeding temperate legumes: Advances and challenges. Lotus Newsl 37(3), 105.
R.A. Morris and D.P. Garrity (1993). Resource capture and utilization in intercropping non-nitrogen nutrients. Field Crops Res 34, 319–334.
O. Oweis, H. Ahmed, and M. Pala (2004a). Lentil production under supplemental irrigation in a Mediterranean environment. Agric Water Manage 68(3), 251–265.
O. Oweis, H. Ahmed, and M. Pala (2005). Fababean productivity under rainfed and supplemental irrigation in northern Syria. Agric Water Manage 73(1), 57–72.
T. Oweis and A. Hachum (2006). Water harvesting and supplemental irrigation for improved water productivity of dry farming systems in West Asia and North Africa. Agric Water Manage 80(1), 57–73 (Special issue of Water Scarcity, Challenges and Opportunities for Crop Science).
T. Oweis, A. Hachum, and M. Pala (2004b). Water use efficiency of winter-sown chickpea under supplemental irrigation in a Mediterranean environment. Agric Water Manage 66(2), 163–179.
R.J. Papendick, M.J. Lindstorm, and V.L. Cochran (1973). Soil mulch effect on seedbed temperature and water during fallow in eastern Washington. Soil Sci Soc Am Proc 37, 307–314.
J.B. Passioura (1977). Grain yield, harvest index and water use of wheat. J Aust Inst Agric Sci 43, 117–120.
J.B. Passioura (1983). Roots and drought resistance. Agric Water Manage 7, 265–280.
PAU (1976). Package of practices for rabi crops of Punjab. Punjab Agricultural University, Ludhiana.
S.S. Prihar and B.S. Sandhu (1968). Irrigation of field crops: Principles and practices. Indian Council of Agricultural Research (ICAR), New Delhi, 142 pp.
R.A. Richards, G.J. Rebetzke, A.G. Condon, and A.F. Van Harwaarden (2002). Breeding opportunities for increasing efficiency of water use and crop yield in temperate cereals. Crop Sci 42, 111–121.
O.P. Rupella and M.C. Saxena (1987). Nodulation and N2-fixation. In: Saxena, M.C., Singh, K.B. (eds.), The chickpea, pp. 191–206. CAB International, Wallingford.
N.P. Saxena, L. Krishnamurthy, and C. Johansen (1993). Registration of a drought resistant chickpea germplasm. Crop Sci 33, 1424.
H.S. Sekhon, G. Singh, J.S. Chandi, V. Sardana, I. Singh, and H. Ram (2004). Effects of planting methods and irrigation on the productivity of chickpea sown after rice. Int Chickpea Pigeonpea Newsl 11, 22–25.
R. Serraj, H.K. Buhariwala, K.K. Sharma, P.M. Gaur, and J.M. Crouch (2004). Crop improvement of drought resistance in pulses: A holistic approach. Indian J Pulses Res 17, 1–13.
R. Serraj and T.R. Sinclair (2002). Osmolyte accumulation. Can it really help increase crop yield under drought condition. Plant Cell Environ 25, 333–341.
Z. Shen, L. Wang, F. Yu, and B. Liu (2000). New concept of water saving-study and application of real water saving. China Water Power Press, Beijing.
T. Si, W. Zhang, and D. Jia (1992). A new irrigation technique for saving water and increasing yield – Irrigation on film under wheat-cotton intercropping. In: Xu, Y., Lin, C., Shalhevet, J. (eds.), Water use efficiency in agriculture, pp. 183–188. Science Press, Beijing.
K.H.M. Siddique, K.L. Regan, S.P. Loss, and R. Jettener (1999). Adaptation of cool season grain legumes in Mediterranean-type environments of south-western Australia. Aust J Agric Res 50, 375–387.
K.H.M. Siddique, K.L. Regan, D. Tennant, and B.D. Thomson (2001). Water use and water use efficiency of cool season grain legumes in low rainfall Mediterranean-type environment. Eur J Agron 15(4), 267–280.
A.S. Sidhu and H.S. Sur (1993). Effect of incorporation of legume straw on soil properties and crop yield in a maize-wheat sequence. Trop Agric 70, 226–229.
S.V. Silim and M.C. Saxena (1993). Adaptation of spring sown chickpea to the Mediterranean basin. 1. Response to moisture supply. Field Crops Res 34, 121–136.
D.P. Singh (2002). Drought management in field crops. In: Singh, G., Kolart, J.S., Sekhon, H.S., (eds.), Recent Advances in Agronomy, pp. 253–277. Indian Society of Agronomy, New Delhi.
D.P. Singh and R.K. Pannu (1998). Irrigation management in field crops. In: Yadav, R.L., Singh, P., Prasad, S., Ahlawat, I.P.S. (eds.), Fifty years of agronomic research in India, pp. 87–140. Indian Society of Agronomy, New Delhi.
S. Singh, S.S. Saini, and B.P. Singh (2004). Effect of irrigation, sulphur and seed inoculation on growth, yield and sulphur uptake of chickpea (Cicer arieitnum L.) under late sown conditions. Indian J Agron 49, 57–59.
P. Singh and Y.V. Sri Rama (1989). Influence of water deficit on transpiration and radiation use efficiency of chickpea (Cicer arietinum L.). Agric Forest Meteorol 48, 317–330.
R.K. Sivanappan (1995). Need for holistic approach: Water management. The Hindu Survey of Indian Agriculture, pp. 156–159.
J.I. Sprent, F.R. Minchin, and R.J. Thomas (1983). Environmental effects on physiology of nodulation and nitrogen fixation. In: Jones, D.G., Davis, D.R. (eds.), Temperate legumes: Physiology, genetics and nodulation, pp. 269–318. Pitman Books, London.
R.J. Summerfield, F.R. Minchin, E.H. Roberts, and P. Hadley (1981). Adaptation to contrasting areal environments in chickpea (Cicer arietinum L.). Trop Agric 2, 97–113.
R. Sun, K. Wu, and S. Liu (1992). Analysis on water-saving benefit of border irrigation with different sized plots. In: Xu, Y., (ed.), Study on water saving agriculture, pp. 194–199. Science Press, Beijing.
C.B. Tanner and T.R. Sinclair (1983). Efficient water use in crop production: Research or re-research?. In: Taylor, H.M. (ed.), Limitations to efficient water use in crop production, pp. 1–27. American Society of Agronomy, Madison, WI.
K. Tesfaye (2004). Field comparison of resource utilization and productivity of three grain legume species under water stress. Ph.D. Thesis, University of the Free State, South Africa.
K. Tesfaye, S. Walker, and M. Tsubo (2006). Radiation interception and radiation use efficiency of three grain legumes under water deficit conditions in a semi-arid environment. Eur J Agron 25, 60–70.
N.C. Turner (1986). Crop water deficits: A decade of progress. Adv Agron 9, 1–51.
F.P. Valzano, R.S.B. Greene, and B.W. Murphy (1997). Direct effects of stubble burning on soil hydraulic properties in a direct drill tillage system. Soil Tillage Res 5, 391–398.
H.X. Wang, C.M. Liu, and L. Zhang (2002). Water saving agriculture in China: An overview. Adv Agron 75, 135–171.
Z. Wang, Y. Xiong, and M. Wang (2000). Study on expert system of irrigation forecast and decision making for water saving. Institute of Agricultural Soil Water Engineering of North West Science and Technology University of Agriculture & Forestry, Yangling, Shaanxi.
J. Wery, O. Turc, and J. Lecoeur (1993). Mechanisms of resistance to cold, heat and drought in cool season food legumes with special reference to chickpea and pea. In: Singh K.B. and Saxena M.C. (eds.), Breeding for stress tolerance in cool season food legumes, pp. 271–291. Wiley, Chichester.
W.W. Wilhelm, H. Bourszerzour, and J.F. Power (1989). Soil disturbance-residue management effect on winter wheat growth and yield. Agron J 81, 581–588.
L.K. Xu and T.C. Hsiao (2005). Predicted versus measured photosynthetic water-use efficiency of crop stands under dynamically changing field environments. J Exp Bot 55(407), 2395–2411.
J. Zhang, H.T. Nguyen, and A. Blum (1999). Genetic analysis of osmotic adjustment in crop plants. J Exp Bot 50, 291–302.
H. Zhang, M. Pala, T. Oweis, and H. Harris (2000). Water use and water-use efficiency of chickpea and lentil in Mediterranean environment. Aust J Agric Res 5(2), 295–304.
S. Zhang, L. Shan, and X.P. Deng (2002). Change of water use efficiency and its relation with root system growth in wheat evolution. Chin Sci Bull 47, 1879–1883.
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Sekhon, H.S., Singh, G., Sharma, P., Bains, T. (2010). Water Use Efficiency Under Stress Environments. In: Yadav, S., Redden, R. (eds) Climate Change and Management of Cool Season Grain Legume Crops. Springer, Dordrecht. https://doi.org/10.1007/978-90-481-3709-1_12
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