Paddy and Water Environment

, Volume 12, Issue 1, pp 193–202 | Cite as

Productivity and socio-economic impact of system of rice intensification and integrated crop management over conventional methods of rice establishment in eastern Himalayas, India

  • Mokidul Islam
  • L. K. Nath
  • D. P. Patel
  • Anup Das
  • G. C. Munda
  • Tanmay Samajdar
  • S. V. Ngachan
Article

Abstract

To evaluate the performance of new rice establishment methods viz., system of rice intensification (SRI) and integrated crop management (ICM), a field study was conducted during 2008–11 in South Garo Hills, Meghalaya, foot hills of Eastern Himalayas, India. Field demonstrations were undertaken during wet seasons of 2008–11 and socio-economic information in the context of farmer’s realities were obtained during 2010–11 using a well structured questionnaire administered to 134 farmers. The results indicated that the average higher productivity of rice under SRI and ICM demonstration was 209.9 and 185.4 %, respectively, over conventional rice culture (CRC). The SRI and ICM methods of rice cultivation could save seeds (97.56 and 60.98 %), saving water (78.05 and 63.66 %), reduce cost (70.33 %), higher yield etc. compared to CRC. The main reasons for non-adoption of SRI/ICM was related to involvement of more efforts, faith towards traditional practices, ignorance and lack of knowledge on scientific water management. The net-return of $816.69, $706.63 and $51.48/ha was realized under SRI, ICM and CRC, respectively. The co-efficient of multiple determinations (R2) of the production function was 0.695 in SRI, 0.714 in ICM and 0.734 in CRC which indicated that about 69.5, 71.4 and 73.4 % of the variation in rice productivity under SRI, ICM and CRC, respectively were explained by the independent variable and remaining 30.5, 28.6 and 26.6 %., respectively in SRI, ICM and CRC were as a result of non-inclusion of some explanatory variables as well as other factors outside the farmers control.

Keywords

Sustainability Paddies System of rice intensification Integrated crop management Socio-economic impact Water management 

References

  1. Anonymous (2008–09). Government of Meghalaya, Statistical Hand Book, South Garo Hills, IndiaGoogle Scholar
  2. Balasubramanian V, Sie M, Hijmans RJ, Otsuka K (2007) Increasing rice production Sub Saharan Africa: challenges and opportunities. Adv Agron 94:55–126CrossRefGoogle Scholar
  3. Bouman BA, Tuong TP (2001) Field water management to save water and increase its productivity in irrigated lowland rice. Agric Water Manag 49:11–30CrossRefGoogle Scholar
  4. Das Anup, Tomar JMS, Ramesh T, Munda GC, Ghosh PK, Patel DP (2010) Productivity and economics of low land rice as influenced by N-fixing tree leaves under mid-altitude subtropical Meghalaya. Nutr Cycl Agroecosyst 87:9–19CrossRefGoogle Scholar
  5. Das Anup, Ngachan SV, Ramkrushna GI, Choudhury BU, Singh RK, Tripathi AK, Patel DP, Munda GC (2012) Participatory rain water management for enhancing water productivity and livelihood in hill ecosystem: action programme for research applications. ICAR research complex for NEH region, Umiam, p 115Google Scholar
  6. Haque MA, Mustafi BAA, Sarkar AL (1997) Rice production in absentee owners land in rainfed saline area of Bangladesh. Econ Affair 42(1):14–22Google Scholar
  7. Kabir H (2006) Adaptation and adoption of the system of rice intensification (SRI) in Myanmar using the farmer field school (FFS) approach. Ph. D. Diss., University of HonoluluGoogle Scholar
  8. Kumar D, Shivay YS (2004) System of rice intensification. Indian Farming 11:18–21Google Scholar
  9. Maser CM, Barett CB (2003) The disappointing adoption dynamics of a yield increasing low external-input technology: the case of SRI in Madagascar. Agric Syst 76:1084–1100Google Scholar
  10. Munda GC, Ngachan SV, Das A, Malngiang S, Chowdhury S (2012) Site specific farming system options for rural livelihood-success stories from NEH Region. NAIP Bulletin no 2. ICAR Research Complex for NEH Region, Umiam, p78Google Scholar
  11. Nandhini US, Alagumani T, Shibi S (2006) Economic analysis of agriculture in Southern parts of coastal India. Agric Trop ET Subtrop 39(4):279–284Google Scholar
  12. Oniah MO, Kuye OO, Idiong IC (2008) Efficiency of resource use in small scale swamp rice production in Obubra local government Area of cross river state, Nigeria. Middle-East J Sci Res 3(3):145–148Google Scholar
  13. Patel DP, Das A, Munda GC, Ghosh PK, Ngachan SV, Kumar R, Saha R (2008) SRI and ICM rice culture for water economy and higher productivity. Research Bulletin No: 68. ICAR research complex for NEH region, Umiam, pp 1–28Google Scholar
  14. Rajendran R, Balasubramanian V, Ravi V, Valliappan K, Jayaraj T, Ramanathan S (2004) Nursery technology for early production of robust rice seedlings to transplant under integrated crop management. Int Rice Res Notes 29(2):73–75Google Scholar
  15. Rajendran R, Ravi V, Valliappan K, Nadanasabapathy T, Jayaraj T, Ramanathan S, Balasubramanian V (2005) Early production of robust seedlings through modified mat nursery for enhancing rice (Oryza sativa) productivity and profit. Indian J Agron 50(20):132–136Google Scholar
  16. Rao KS, Annie Poonam, Ghosh A, Mohapatia PC, Pandey MP (2007) Present status Of SRI research at CRRI, Cuttack, India, 2nd National Symposium on SRI in India: progress and prospects-papers and extended summaries, 3rd–5th Oct 2007. Agartala, Tripura, pp 35–37Google Scholar
  17. Satyanarayana A, Thiyagarajan TM, Uphoff N (2006) Opportunities for water saving with higher yield from the system of rice intensification. Irrigation Science. Springer, BerlinGoogle Scholar
  18. Shekhar J, Mamkotia BS, Dev SP (2009) Productivity and economics of rice (Oryza sativa) in system of rice intensification in North-Western Himalayas. Indian J Agron 54(4):423–427Google Scholar
  19. Shobarani N, Prasad GSV, Prasad ASR, Sailaja B, Muthuraman P, Numeera S, Viraktamath BC (2010) Rice Almanac: India. DRR Technical Bulletin No 5, directorate of rice research, Rajendranagar, Hyderabad, pp 6–7Google Scholar
  20. Singh SP, Kumar RM, Sreedevi B, Krishnamurthy P, Subbaiah SV (2007) System of rice intensification and integrated crop management for sustaining rice production under irrigated ecosystem. In second national symposium on SRI, Agartala, 3–5 Oct 2007, pp 55–56Google Scholar
  21. Sinha SK, Talati J (2007) Productivity impacts of the system of rice intensification (SRI): a case study in West Bengal, India. Agric Water Manag 87:55–60CrossRefGoogle Scholar
  22. Sita Devi K, Ponnarasi T (2009) An economic analysis of modern rice production technology and its adoption behaviour in Tamil Nadu. Agricultural economics research review, vol 22 (conference number), pp 341–347Google Scholar
  23. Solaimalai A, Sivakumar C, Chandrasekaran R, Sankaranarayanan K, Sudhakar G (2000) Water management practices for rice—a review. Agric Rev 21:53–59Google Scholar
  24. Stoop WA, Uphoff N, Kassam A (2002) A review of agricultural research issues raised by the system of rice intensification (SRI) from Madagascar: opportunities for improving farming systems for resource poor farmers. Agric Syst 71:249–274CrossRefGoogle Scholar
  25. Suresh A, Reddy TRK (2006) Resource use efficiency of paddy cultivation in speech command area of Thrissur district of Kerala: an economic analysis. Agric Econ Res Rev 19:159–171Google Scholar
  26. Timsina J, Connor DJ (2001) Productivity and management of rice–wheat cropping systems: issues and challenges. Field Crops Res 69:93–142CrossRefGoogle Scholar
  27. Uphoff N (2001) Understanding SRI? Appropr Technol 28(3):12–13Google Scholar
  28. Uphoff N (2003) SRI: higher yields with fewer external input ? The system of rice intensification and potential contributions to agricultural sustainability. Int J Agric Sustain 1(1):38–50CrossRefGoogle Scholar
  29. Uphoff N (2004) SRI: the system of rice intensification: an opportunity for raising productivity in the 21st Century. Paper presented in the international year of rice conference, FAO, international institute for food, agriculture and development, Rome, 12–13 Feb 2004Google Scholar
  30. Uphoff N (2005) Features of the system of rice intensification (SRI) apart from increases in yield. http://ciifad.cornell.edu/SRI/yielduphoffrpt505.pdf. Accessed 20 April 2013
  31. Uphoff N (2007) Evaluation and spread of the system of rice intensification (SRI) in Asia. In Second National Symposium on SRI, Agartala, 3–5 Oct 2007, pp 12–23Google Scholar
  32. Uphoff N, Fernandes EC, Yuan LP, Peng J, Rafaralahy S, Rabenandrasana J (eds) (2002) Assessing the system of rice intensification: proceedings of an international conference, Sanya, China, cornell international institute for food, agriculture and development, Ithaca. http://ciifad.cornell.edu/sri/. Accessed 1–4 April 2002
  33. Wang S, Cao W, Jiang D, Dai T, Zhu Y (2002) Physiological characteristics and high-yield techniques for SRI rice. In assessments of the system of rice intensification: proceedings of an international conference, Sanya, China, Cornell International Institute for Food, Agriculture and Development, Ithaca, 1–4 April 2002, pp 116–124Google Scholar
  34. Zeng J, Lu X, Tang X, Tang Y (2004) The system of rice intensification (SRI) for getting super high yields of rice in Sichuan Basin, 4th International Crop Science Congress, Brisbane, Australia. hhtp://www.ciifad.cornell.edu/sri/countries. Accessed 20 April 2013

Copyright information

© Springer Japan 2013

Authors and Affiliations

  • Mokidul Islam
    • 1
  • L. K. Nath
    • 1
  • D. P. Patel
    • 1
  • Anup Das
    • 1
  • G. C. Munda
    • 1
  • Tanmay Samajdar
    • 1
  • S. V. Ngachan
    • 1
  1. 1.ICAR Research Complex for NEH RegionUmiamIndia

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