Combined effect of reduced dose of gypsum and salt tolerant varieties of rice (Oryza sativa) and wheat (Triticum aestivum) on rice-wheat cropping system in sodic soils
DOI:
https://doi.org/10.59797/ija.v54i1.4773Keywords:
Cropping system, Economics, Gypsum, Rice, Salt tolerance, Sodic soils, WheatAbstract
A field experiment was conducted at Lucknow in Uttar Pradesh during 2001-2002 to 2003-04 on a fine loamy, mixed, hyperthermic, sodic soil having high pH, low electrical conductivity, high exchangeable sodium percentage and very low water permeability to find out the combined effect of reduced dose of gypsum and salt tolerant variet- ies of rice ( Oryza sativa L.) and wheat ( Tr iticum aestivum L. emend. Fiori & Paol.) on productivity of rice - wheat cropping system in sodic soil. This study revealed that application of gypsum @ 25% gypsum requirement (G.R.) and growing of salt tolerant varieties of rice CSR 13 and wheat KRL 19 significantly increased the yield attributes and yields of these crops in the system over control treatment as well as 15% G.R. So much so it was at par with 50% G.R. with non- salt tolerant varieties. The magnitude of combined effect of reduced dose of gypsum and salt tolerant varieties was reflected as 17 and 8.2% increase in grain yield over their counterpart varieties. Interaction between gypsum levels and salt-tolerant varieties on grain yields indicated that gypsum @ 25% G.R. with sodicity tolerant varieties in rice-wheat cropping system could save about 43% of the total initial expenditure for the recla- mation of sodic soils over the recommended dose of gypsum (50% G.R.) with non-sodicity tolerant traditional high yielding varieties. Thus, for low-cost effective technology, treating the sodic soils with reduced dose of gypsum (25% G.R.) and growing salt tolerant varieties of rice 'CSR 13' and wheat 'KRL 19' proved highly economical and sustainable technology for resource scarce situations.References
Abrol, I.P. and Bhumbla D.R.1979. Crop responses to different gypsum applications in a highly sodic soil and the tolerance of several crops to exchangeable sodium under field conditions. Soil Science 127: 79-85.
Acharya, C.L. and Abrol, I.P. 1991. Soil- water relation and root-water extraction in alkali soils. Bulletin. 16, CSSRI, Karnal.
Brechtel, H.M. 1976. Application of an inexpensive double ring infiltration: hydrological techniques for upstream conservation. Conservation Guide 2, Food and Agricultural Organization (FAO), Rome.
Chhabra, R. and Abrol. I. P. 1977. Reclaiming effect of rice grown in sodic soils. Soil Science 124: 49-55.
Chhabra, R., Singh, N.T., and Hansen, A. 1989. Interaction between type of amendment and P availability. Annual Report. Cen
tral Soil Salinity Research Institute, Karnal, India. p.38.
Dutta, K.K. and Joshi, P.K. 1996. Technological options for reclamation of salt affected soil under resource constraint Environment in Uttar Pradesh. Agricultural Situation in India. April 1996.
Mishra, B., Bhattacharya, R.K. and Singh, R.K. 1992. 'CSR-10', a newly developed high-yielding salt tolerant rice variety. International Rice Research Notes 17(1): 19.
Anonymous, 1996. Mapping salt affected soils of India, 1:250,000 map sheets, legend. National Remote Sensing Application Center, NRSA, Hyderabad.
Schoonover, W.R. 1952. Examination of Soils for Alkali. University of California, Extension Service, Berkely, California, USA.
Swarup, A. and Singh, K.N. 1993. Ameliorative effect of gypsum, FYM and nitrogen in a sodic soil. Annual Report, Central Soil Salinity Research Institute, Karnal.
