Hostname: page-component-78c5997874-j824f Total loading time: 0 Render date: 2024-11-14T16:58:00.876Z Has data issue: false hasContentIssue false
  • English
  • Français

TILLAGE AND ESTABLISHMENT METHOD IMPACTS ON LAND AND IRRIGATION WATER PRODUCTIVITY OF WHEAT–RICE SYSTEM IN NORTH-WEST INDIA

Published online by Cambridge University Press:  13 April 2016

RAJAN BHATT  and
S. S. KUKAL
RAJAN BHATT
Affiliation:
Department of Soil Science, Punjab Agricultural University, Ludhiana-141004, India
S. S. KUKAL*
Affiliation:
Department of Soil Science, Punjab Agricultural University, Ludhiana-141004, India
*
Corresponding author. Email: sskukal@rediffmail.com
Get access Rights & Permissions [Opens in a new window]

Summary

The resource conservation technologies (RCTs), being advocated for countering the threat to the sustainability of wheat–rice cropping system (RWCS) in the north–west (NW) Indo-Gangetic Plains (IGP) of India, have been evaluated mostly for the individual crops, without depicting the impact of these technologies on the succeeding or preceding crop. A study was thus conducted during 2012–2014 in NW India to assess the land and irrigation water productivity (WPI) of RWCS under different establishment and conservation tillage techniques in a sandy-loam soil (coarse loamy, calcareous, mixed, hyperthermic Typic Ustochrept). The treatments included zero (ZTW) and conventional (CTW) tillage in wheat as main plot, establishment methods (direct seeded (DSR) and mechanically transplanted rice (MTR)) as sub-plot and tillage in rice viz. puddle (PR), dry (CTR) and zero (ZTR) tillage as sub–sub plot treatments, replicated thrice in split–split plot design. The land productivity of RWCS was significantly lower in ZTW plots than in CTW plots. The residual effect of tillage in wheat on rice productivity was distinct during the second year of study, when the CTW plots recorded significantly higher (17.5%) rice yield than the ZTW plots. The productivity of the cropping system with DSR was statistically similar to that with MTR. The WPI of RWCS increased in the order ZTW–DSR–ZTR25 < CTW–DSR–ZTR < ZTW–MTR–CTR < ZTW–DSR–PR < CTW–DSR–PR < ZTW–MTR–PR26 < CTW–MTR–PR.

Type
Research Article
Information
Experimental Agriculture , Volume 53 , Issue 2 , April 2017 , pp. 178 - 201
Check for updates
Copyright
Copyright © Cambridge University Press 2016 

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

REFERENCES

Aggarwal, G. C., Sidhu, A. S., Sekhon, N. K., Sandhu, K. S. and Sur, H. S. (1995). Puddling and N management effects on crop response in a rice–wheat cropping system. Soil and Tillage Research 36:129139.CrossRefGoogle Scholar
Bhatt, R. and Khera, K. L. (2006). Effect of tillage and mode of straw mulch application on soil erosion losses in the submontaneous tract of Punjab, India. Soil and Tillage Research 88:107115.Google Scholar
Bhatt, R. and Kukal, S. S. (2014). Resource conservation techniques for mitigating the water scarcity problem in the Punjab, India - a review. International Journal of Earth Sciences and Engineering 7:309316.Google Scholar
Bhatt, R. and Kukal, S. S. (2015). Direct seeded rice for improving water productivity and livelihood in South Asia. Sustainable Agriculture Reviews 18:217252.Google Scholar
Dawe, D. (2005). Increasing water productivity of rice-based cropping systems in Asia – past trends, current problems, and future prospects. Plant and Food Science 8:221230.Google Scholar
Devkota, K. P., Lamersb, J. P. A., Manschadic, A. M., Devkotad, M., McDonald, A. J. and Vlek, P. L. G. (2015). Comparative advantages of conservation agriculture based rice–wheat rotation systems under water and salt dynamics typical for the irrigated arid drylands in Central Asia. European Journal of Agronomy 62:98109.CrossRefGoogle Scholar
Erenstein, O. (2011). Livelihood assets as a multidimensional inverse proxy for poverty: A district level analysis of the Indo-Gangetic Plains. Journal of Human Development 2:283302.Google Scholar
FAO. (2010). FAOSTAT Database: Agriculture Production. Rome: Food and Agriculture organization of the United Nations.Google Scholar
Gathala, M. K., Ladha, J. K., Kumar, V., Saharawat, Y. S., Kumar, V., Sharma, P. K., Sharma, S. and Pathak, H. (2011). Tillage and crop establishment affects sustainability of South Asian rice-wheat system. Agronomy Journal 103:961971.Google Scholar
Gleick, P. H. (Ed). (1993). Water in Crisis - a Guide to the World's Freshwater Resources. New York: Oxford Univ. Press.Google Scholar
Guan, D., Zhang, Y., Kaisi, M. M. A., Wang, Q., Zhang, M. and Li, Z. (2015). Tillage practices effect on root distribution and water use efficiency of winter wheat under rain-fed condition in the North China Plain. Soil and Tillage Research 146:286295.Google Scholar
Hira, G. S. (2004). Status of water resources in Punjab and management strategies. In Workshop Papers of Groundwater Use in NW India, New Delhi, India, 65.Google Scholar
Hira, G. S. (2009). Water management in northern states and the food security of India. Journal of Crop Improvement 23:136157.Google Scholar
Hobbs, P. R., Sayre, K. and Gupta, R. (2008). The role of conservation agriculture in sustainable agriculture. Philippines Transactions of Royal Society 363:543555.CrossRefGoogle ScholarPubMed
Humphreys, E., Kukal, S. S., Christen, E. W., Hira, G. S., Singh, B., Yadav, S. and Sharma, R. K. (2010). Halting the groundwater decline in north-west India-which crop technologies will be winners? Advances in Agronomy 109:156199.Google Scholar
Jat, M. L., Gathala, M. K., Ladha, J. K., Saharawat, Y. S., Jat, A. S., Kumar, V., Sharma, S. K., Kumar, V. and Gupta, R. (2009). Evaluation of precision land leveling and double zero till systems in the rice–wheat rotation: Water use, productivity, profitability and soil physical properties. Soil and Tillage Research 105:112121.Google Scholar
Jat, M. L., Singh, S., Rai, H. K., Chhokar, R. S., Sharma, S. K. and Gupta, R. K. (2005). Furrow irrigated raised bed (FIRB) planting technique for diversification of rice-wheat system in Indo-Gangetic Plains. Proceedings of Japan Association of International Collaboration of Agriculture and Forest 28:2542.Google Scholar
Jat, R. K., Sapkota, T. B., Singh, R. G., Jat, M. L., Kumar, M. and Gupta, R. K. (2014). Seven years of conservation agriculture in a rice–wheat rotation of eastern gangetic plains of South Asia: Yield trends and economic profitability. Field Crops Research 164:199210.Google Scholar
Kamboj, B. R., Yadav, D. B., Yadav, A., Goel, N. K., Gil, G., Malik, R. K. and Chauhan, B. S. (2013). Mechanized transplanting of rice (Oryza sativa L.) in non-puddled and no-till conditions in the rice-wheat cropping system in Haryana, India. American Journal of Plant Science 4:24092413.CrossRefGoogle Scholar
Kukal, S. S. and Aggarwal, G. C. (2003a). Puddling depth and intensity effects in rice-wheat system on a sandy loam soil. I. Development of subsurface compaction. Soil and Tillage Research 72:18.CrossRefGoogle Scholar
Kukal, S. S. and Aggarwal, G. C. (2003b). Puddling depth and intensity effects in rice-wheat system on a sandy loam soil II. Water use and crop performance. Soil and Tillage Research 74:3745.Google Scholar
Kukal, S. S., Hira, G. S. and Sidhu, A. S. (2005). Soil matric potential-based irrigation scheduling to rice (Oryza sativa). Irrigation Science 23:153159.Google Scholar
Kukal, S. S. and Sidhu, A. S. (2004). Percolation losses of water in relation to pre-puddling tillage and puddling intensity in a puddled sandy loam rice. Soil and Tillage Research 78:18.Google Scholar
Kukal, S. S., Singh, Y., Jat, M. L. and Sidhu, H. S. (2014). Improving water productivity of wheat-based cropping systems in South Asia for sustained productivity. Advances in Agronomy 127:159230.Google Scholar
Kukal, S. S., Yadav, S., Kaur, A. and Singh, Y. (2009). Performance of rice (Oryza sativa) and wheat (Triticum aestivum) on raised beds in farmers’ scale field plots. Indian Journal of Agricultural Sciences 79:7578.Google Scholar
Kumar, V. and Ladha, J. K. (2011). Direct seeding of rice: Recent developments and future research needs. Advances in Agronomy 111:297313.Google Scholar
Mosaddeghi, M. R., Mahboubi, A. A. and Safadoust, A. (2009). Short term effects of tillage and manure on some soil physical properties and wheat root growth in a sandy loam soil in western Iraq. Soil and Tillage Research 104:173179.Google Scholar
Naresh, R. K., Singh, S. P. and Kumar, V. (2013). Crop establishment, tillage and water management technologies on crop and water productivity in rice-wheat cropping system of northwest India. International Journal of Life Sciences. Biotechnology and Pharma Research 2:237248.Google Scholar
Rashid, M. H., Alam, M. M., Khan, M. A. H. and Ladha, J. K. (2009). Productivity and resource use of direct-(drum)-seeded and transplanted rice in puddled soils in rice-rice and rice-wheat ecosystem. Field Crops Research 113:274281.Google Scholar
Rejesus, R. M., Palis, F. G., Rodriguez, D. G. P., Lampayan, R. M. and Bouman, B. A. M. (2011). Impact of the alternate wetting and drying (AWD) water-saving irrigation technique: Evidence from rice producers in the Philippines. Food Policy 36:280288.Google Scholar
Saharawat, Y. S., Singh, B., Malik, R. K., Ladha, J. K., Gathala, M., Jat, M. L. and Kumar, V. (2010). Evaluation of alternative tillage and crop establishment methods in a rice-wheat rotation in North Western IGP. Field Crops Research 116:260267.Google Scholar
Singh, B., Humphreys, E., Eberbach, P. L., Katupitiya, A., Singh, Y. and Kukal, S. S. (2011). Growth, yield and water productivity of zero till wheat as affected by rice straw mulch and irrigation schedule. Field Crops Research 121:209225.Google Scholar
Singh, M., Bhullar, M. S. and Chauhan, B. S. (2015a). Influence of tillage, cover cropping, and herbicides on weeds and productivity of dry direct-seeded rice. Soil and Tillage Research 147:3949.Google Scholar
Singh, M., Bhullar, M. S. and Chauhan, B. S. (2015b). Seed bank dynamics and emergence pattern of weeds as affected by tillage systems in dry direct-seeded rice. Crop Protection 67:168177.Google Scholar
Singh, Y., Humphreys, E., Kukal, S. S., Singh, B., Kaur, A., Thaman, S., Prashar, A., Yadav, S., Kaur, N., Dhillon, S. S., Smith, D. J., Timsina, J. and Gajri, P. R. (2009). Field Crops Research 110: 120.Google Scholar
Sur, H. S., Prihar, S. S. and Jalota, S. K. (1981). Effect of rice-wheat and maize-wheat rotations on water transmission and wheat root development in a sandy loam of the Punjab, India. Soil and Tillage Research 1:361371.Google Scholar
Tuong, T. P. and Bouman, B. A. M. (2003). Rice production in water-scarce environments. In Water Productivity in Agriculture: Limits and Opportunities for Improvement, 5367 (Eds Kijne, J. W., Barker, R. and Molden, D.). UK: CABI Publishing.Google Scholar
Yadav, S., Evangelista, G., Faronilo, J., Humphreys, E., Henry, A. and Fernandez, L. (2014). Establishment method effects on crop performance and water productivity of irrigated rice in the tropics. Field Crops Research 166:112127.Google Scholar
Yadav, S., Gill, G., Humphreys, E., Kukal, S. S. and Walia, U. S. (2011). Effect of water management on dry seeded and puddle transplanted rice. Part-1. Crop performance. Field Crops Research 120:112122.CrossRefGoogle Scholar