Effects of sources of phosphorus and biofertilizers on productivity and profitability of soybean (Glycine max)wheat (Triticum aestivum) system
DOI:
https://doi.org/10.59797/ija.v53i4.4873Keywords:
Cropping system, Phosphorus-use efficiency, Productivity, Soybean, WheatAbstract
A field experiment was carried out during 2005-06 and 2006-07 at New Delhi to study the effect of different sources of phosphorus [single superphosphate (SP) and rock phosphate (RP)] and biofertilizers (phosphate-solu- bilizing bacteria and vesicular-arbuscular mycorrhiza) on productivity, nutrient uptake, P balance in the soil, phos- phorus-use efficiency and economics of soybean [ Glycine max (L.) Merr.]wheat ( Tr iticum aestivum L. emend. Fiori & Paol.) cropping system. Application of 50% recommended dose of P as SP + PSB + VAM recorded the highest yield during the first year in soybean (2.0 t/ha) and during both the years in wheat (4.4 and 4.6 t/ha in the first and second years respectively), but that of 50% RD Pas RP + PSB + VAM registered the highest grain yield (2.2 t/ha) during the second year in soybean. P uptake and utilization efficiencies increased on application of both PSB and VAM under both the sources of P. In addition, the available P status of the soil improved by addition of both bio-fertilizers through both the sources. RP performed very poorly, but when inoculated with both the bio-fertil- izers, it was comparable to SP. Although the highest net returns per rupee invested was observed in 0.5 RP+PSB+VAM, but 0.5 SP+PSB+VAM provided highest net returns of 34.4 and 41.3 thousand rupees in first and second years respectively, it gave benefit: cost ratio (B:C) very close to that of the previous treatment in the soy- bean-wheat cropping system. Thus half the dose of P could be saved through inoculation with both P-solubilizing and mobilizing micro-organisms to obtain higher productivity and profitability.References
Behera, U.K., Sharma, A.R. and Pandey, H.N. 2007. Sustaining
productivity of wheat-soybean cropping system through in
tegrated nutrient management practices on the vertisols of
central India. Plant and Soil 297: 185199. FAI. 2007. Fertilizer Statistics 200607. The Fertilizer Association
of India, New Delhi.
Kucey, R.M.N., Tanzen, H.H. and Leggett, M.E. 1989. Microbially mediated increase in plant available phosphorus. Advances in Agronomy 42: 199228.
Ogoke, I.J., Togun, A.O. and Dashiell, K.E. 2006. Soybean phosphorus use efficiency in the moist savanna of West Africa. Journal of Sustainable Agriculture 28: 518.
Panda, B.B. 2002. Influence of phosphate solubilizing and mobilizing microorganisms on phosphorus use efficiency in wheat using 32P as a tracer. Ph.D. thesis, IARI, New Delhi.
Singh, H.P., Srinivas, K. and Sharma, K.L. 2001. Phosphorus management in dryland agriculture, pp. 162168. Proceedings of National Workshop on Phosphorus in Indian Agriculture: Issues and Strategies held at New Delhi.
Stauffer, M.D. and Sulewski, G. 2001. Phosphorus: essential for life, pp. 714. Proceedings of National Workshop on Phosphorus in Indian Agriculture: Issues and Strategies held at New Delhi.
Tarafdar, J.C. and Marschener, H. 1994. Phosphatase activity in the rhizosphere and hyposphere of VA mycorrhizal wheat supplied with inorganic and organic phosphorus. Soil Biology and Biochemistry 26: 387395.
Zaidi, A., Khan, M.S. and Amil, M. 2003. Interactive effect of rhizotropic microorganisms on yield and nutrient uptake of chickpea. European Journal of Agronomy 19: 1521.
