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Assessing the impact of water-saving technologies on Boro rice farming in Bangladesh: economic and environmental perspective

  • Md. Taj Uddin
  • Aurup Ratan DharEmail author
Original Paper
  • 22 Downloads

Abstract

The study was conducted to evaluate the economic and environmental impacts of water-saving technologies (WST) on Boro rice (Oryza sativa; var. BRRIdhan 29) farming in Bangladesh. A total of 480 farmers (80 focal and 400 control) were selected as sample from Mymensingh, Comilla, Bogra and Gaibandha districts. Focal farmers were selected purposively and a limited amount of financial support was provided to them to implement WST. On the other hand, control farmers were selected randomly. They did not receive any financial support and continued practicing conventional irrigation methods. For analyzing the data, a combination of descriptive, mathematical and statistical techniques was used. The study revealed that 62.5 and 37.5% of focal farmers adopted alternate wetting and drying (AWD) and system of rice intensification (SRI) methods, respectively, where the majority of them were within the late majority group in terms of adoption. The profitability and productivity of Boro rice, as well as water productivity, were comparatively higher for focal farmers compared to control farmers. Furthermore, focal farmers’ irrigation amount for producing Boro rice  was significantly lower than control farmers. The study also revealed that focal farmers’ income from rice production was 24.6% higher than control farmers. Input support, motivation, training programs and extension services are recommended to implement to raise the awareness and enrich the knowledge of the farmers on water-saving technologies.

Notes

Acknowledgement

The authors are thankful to the Ministry of Education (MoE), Government of the People’s Republic of Bangladesh for funding to conduct this study.

Compliance with ethical standards

Conflict of interest

On behalf of all authors, the corresponding author states that there is no conflict of interest.

References

  1. Alam MS, Islam MS, Salam MA, Islam MA (2009) Economics of alternate wetting and drying method of irrigation: evidences from farm level study. Agriculturists 7(1&2):82–89Google Scholar
  2. Balasubramaniam P, Vijayaraghavan R, Selvaraj G (2009) An Analysis on Micro- irrigation System. Agropedia. http://agropedia.iitk.ac.in/content/analysis-micro-irrigation
  3. Barker R, Dawe D, Inocencio A (2003) Economics of Water Productivity in Managing Water for Agriculture. Water Productivity in agriculture: limits and opportunities for improvement, CABI Publishing in association with International Water Management Institute, United KingdomGoogle Scholar
  4. Berbel J, Gutiérrez-Martín C, Expósito A (2018) Impacts of irrigation efficiency improvement on water use, water consumption and response to water price at field level. Agric Water Manag 203:423–429CrossRefGoogle Scholar
  5. Bouman, B. 2012. Smart Rice Cultivation: Plastic Tube Irrigation Saves Water and Boosts Harvest. Gaia Discovery. https://www.gaiadiscovery.com/agriculture-industry/smart-rice-cultivation-plastic-tube-irrigation-saves-water-a.html
  6. Cabangon R, Lampayan R, Bouman B, Tuong TP (2014) Water saving technologies for rice production in the Asian region. Food and Fertilizer Technology Center, TaipeiGoogle Scholar
  7. Cook S, Gichuki F, Turral H (2006) Agricultural water productivity: estimation at plot, farm and basin scale. Basin Focal Project Working Paper No. 2, CGIAR Challenge Program on Water and Food. http://ageconsearch.umn.edu/bitstream/91959/2/H039742.pdf. Accessed 24 Mar 2018
  8. DFID (2000) Sustainable livelihoods guidance sheets. Department for International Development, LondonGoogle Scholar
  9. Dharmasiri LM (2009) Measuring agricultural productivity using the average productivity index (API). Sri Lanka J Adv Soc Stud 1(2):25–44Google Scholar
  10. Dillon JL, Hardaker JB (1993) Farm management research for small farmer development. FAO, RomeGoogle Scholar
  11. Duttarganvi S, Tirupataiah K, Yella RK, Sandhyrani K, Mahendra KR, Kadasiddappa M (2014) Yield and water productivity of rice under different cultivation practices and irrigation regimes. International Symposium on Integrated Water Resources Management (IWRM-2014), 19–21 February, Kerala, IndiaGoogle Scholar
  12. FAO (1996) Irrigation scheduling: from theory to practice. Food and agriculture Organization of the United Nations. Proceedings of the ICID/FAO Workshop on Irrigation Scheduling, 12–13 September, Rome, ItalyGoogle Scholar
  13. FAO (2013) Rice farming: saving water through alternate wetting drying (AWD) Method, Indonesia. Available at http://www.fao.org/3/ca4023en/ca4023en.pdf. Accessed 30 Oct 2019
  14. Foster GR (2001) Keynote: soil erosion prediction technology for conservation planning. http://www.tucson.ars.ag.gov/isco/isco10/SustainingTheGlobalFarm/K005-Foster.pdf
  15. Gujarati DN (2003) Basic econometrics. McGraw-Hill, New YorkGoogle Scholar
  16. Gürel E, Tat M (2017) SWOT analysis: a theoretical review. J Int Soc Res 10(51). https://www.researchgate.net/publication/3193677_SWOT_ANALYSIS_A_THEORETICAL_REVIEW. Accessed 16 Mar 2018CrossRefGoogle Scholar
  17. HDR, 2015. Human Development Report, Work for Human Development, United Nations Development Programme, New York, United States of AmericaGoogle Scholar
  18. HIES (2016) Preliminary report on household income and expenditure survey, Bureau of Statistics Division, Ministry of Planning. Government of the People’s Republic of Bangladesh, DhakaGoogle Scholar
  19. Huang Q, Wang J, Li Y (2016) Do water saving technologies save water? Empirical Evidence from North China. J Environ Econ Manag.  https://doi.org/10.1016/j.jeem.2016.10.003 CrossRefGoogle Scholar
  20. Husain MM, Alam MS, Kabir MH, Khan AK, Islam MM (2009) Water saving irrigation in rice cultivation with particular reference to alternate wetting and drying method: an overview. Agriculturists 7(1&2):128–136Google Scholar
  21. ICIMOD (2006) System of Rice Intensification (SRI). International Centre for Integrated Mountain Development, NepalGoogle Scholar
  22. IFC (2014) Impact of efficient irrigation technology on small farmers. International Finance Corporation, World Bank Group, Washington, D.C., United States of AmericaGoogle Scholar
  23. Islam MR, Takeuchi W (2018) AWD irrigation techniques in rice paddy irrigation: a great opportunity for Bangladesh. Paper presented at IIS Forum-2018, University of Tokyo, Tokyo, JapanGoogle Scholar
  24. Kabir MS, Salam MU, Chowdhury A, Rahman NMF, Iftekharuddaula KM, Rahman MS, Rashid MH, Dipti SS, Islam A, Latif MA, Islam AKMS, Hossain MM, Nessa B, Ansari TH, Ali MA, Biswas JK (2015) Rice vision for Bangladesh: 2050 and beyond. Bangladesh Rice J 19(2):1–18CrossRefGoogle Scholar
  25. Kammer S (2014) Factors influencing the adoption of soil and water conservation technologies: a case study of two farming communities in rural Ethiopia. MS Thesis, Department of Forest Resources, University of Washington, Seattle, WashingtonGoogle Scholar
  26. Kjine JW, Barker R, Molden D (2003) Water productivity in agriculture. Centre for Agriculture and Bioscience International, WallingfordGoogle Scholar
  27. Kumar DM, Turral H, Sharma BR, Amarasinghe U, Singh OP (2008) Water Saving and Yield Enhancing Micro Irrigation Technologies in India: When Do they Become Best Bet Technologies? Managing Water in the Face of Growing Scarcity, Inequity and Declining Returns: Exploring Fresh Approaches, Proceedings of the 7th Annual Partners’ Meet of IWMI-Tata Water Policy Research program, International Crops Research Institute for the Semi-Arid Tropics (ICRISAT), Hyderabad, IndiaGoogle Scholar
  28. Kürschner E (2010) Water saving in rice production—dissemination, adoption and short term impacts of alternate wetting and drying (AWD) in Bangladesh. SLE Publication Series—S241, Study commissioned by the Advisory Service on Agricultural Research for Development of German Technical Cooperation (GTZ-BEAF) in collaboration with the International Rice Research Institute (IRRI)Google Scholar
  29. Luo J, Rahman MW (2010) Successful Cases of Irrigation Water Management and Technological Advancement in Bangladesh. Yangling International Agri-Science Forum. https://ssrn.com/abstract=1651189
  30. Mann HB, Whitney DR (1947) On a test of whether one of two random variables is stochastically larger than the other. Ann Math Stat 18(1):50–60CrossRefGoogle Scholar
  31. Materu ST, Shukla S, Sishodia RP, Tarimo A, Tumbo SD (2018) Water use and rice productivity for irrigation management alternatives in tanzania. Water.  https://doi.org/10.3390/w10081018 CrossRefGoogle Scholar
  32. Miah MTH, Hardaker JB (1988) Benefit-cost analysis of deep and shallow tubewell projects in the Tangail District in Bangladesh. Bangladesh J Agric Econ 11(1):1–3Google Scholar
  33. Narayanamoorthy A, Devika N, Bhattarai M (2016) More crop and profit per drop of water: drip irrigation for empowering distressed small farmers. IIM Kozhikode Soc Manag Rev 5(1):83–90CrossRefGoogle Scholar
  34. Neogi MG, Uddin AKMS, Uddin MT, Miah MAH (2018) Alternate wetting and drying (AWD) technology: a way to reduce irrigation cost and ensure higher yields of Boro rice. J Bangladesh Agric Univ 16(1):1–4CrossRefGoogle Scholar
  35. Perry C, Steduto P, Allen RG, Burt CM (2009) Increasing productivity in irrigated agriculture: agronomic constraints and hydrological realities. Agric Water Manag 96(11):1517–1524CrossRefGoogle Scholar
  36. Rashid MM, Yasmin R (2017) Cold injury and flash flood damage in boro rice cultivation in bangladesh: a review. Bangladesh Rice J 21(1):13–25CrossRefGoogle Scholar
  37. Rashid MA, Kabir W, Khan LR, Saleh AFM, Khair MA (2009) Estimation of water loss from irrigated rice fields. SAARC J Agric 7(1):29–42Google Scholar
  38. Ravichandran VK, Prakash KC, Nayar V (2015) An evaluation of the SRI on increasing yield, water productivity and profitability; experiences from TN-IAMWARM project. Irrig Drain Syst Eng.  https://doi.org/10.4172/2168-9768.1000137 CrossRefGoogle Scholar
  39. RDA (2015) Water saving technologies. Rural Development Academy, SherpurGoogle Scholar
  40. Rippin N (2016) multidimensional poverty in germany: a capability approach. Forum Soc Econ 45(2–3):230–255CrossRefGoogle Scholar
  41. Rogers EM (1995) Diffusion of innovations, 4th edn. The Free Press, New YorkGoogle Scholar
  42. Samaila S, Ismail WIBW, Kassim MSM (2016) The system of rice intensification (SRI) practices and mechanization needs. Asian J Agric Sci 8(3):10–17Google Scholar
  43. Sattar MA, Maniruzzaman M, Kashem MA (2009) AWD Technology for rice production in Bangladesh. National Workshop Proceedings, Bangladesh Rice Research Institute (BRRI), Gazipur, BangladeshGoogle Scholar
  44. Seidazimova D, Aitbayev T, Kampitova G (2016) Impact of water-saving irrigation technology on yield and quality of white cabbage varieties in the south-east Kazakhstan. International Conference on Agricultural, Civil and Environmental Engineering (ACEE-16), Istanbul, TurkeyGoogle Scholar
  45. Seigel S (1988) Non-parametric statistics for the behavioral sciences, 2nd edn. McGraw Hill, New YorkGoogle Scholar
  46. Sharma SK, Mishra PK, Panse R, Jamliya G (2018) Effect of irrigation methods on yields attributes and water productivity of wheat in Vertisol of Betwa River Basin commands of Vidisha District of M.P., India. Int J Curr Microbiol Appl Sci 7(8):2670–2673CrossRefGoogle Scholar
  47. Sheehy JE, Peng S, Dobermann A, Mitchel PL, Ferrer A, Yang J, Zou Y, Zhong X, Huang J (2004) Fantastic yields in the system of rice intensification: fact or fallacy? Field Crops Res 88(1):1–8CrossRefGoogle Scholar
  48. Shelley IJ, Takahashi-Nosaka M, Kano-Nakata M, Haque MS, Inukai Y (2016) Rice cultivation in Bangladesh: present scenario, problems, and prospects. J Int Cooperat Agric Dev 14:20–29Google Scholar
  49. SRI-Rice, 2010. SRI International Network and Resources Center, College of Agriculture and Life Sciences, Cornell University, New York, United States of AmericaGoogle Scholar
  50. Thakur AK, Rath S, Mandal KG (2013) Differential responses of system of rice intensification (SRI) and conventional flooded-rice management methods to applications of nitrogen fertilizer. Plant Soil 370(1&2):59–71CrossRefGoogle Scholar
  51. Thakur AK, Singh R, Kumar A (2014) The science behind the system of rice intensification (SRI). Research Bulletin No. 69, Directorate of Water Management (ICAR), Odisha, IndiaGoogle Scholar
  52. Uddin MT, Dhar AR (2016) Conservation agriculture practice and its impact on farmer’s livelihood status in Bangladesh. SAARC J Agric 14(1):119–140CrossRefGoogle Scholar
  53. Uddin MT, Dhar AR (2018) Government input support on Aus rice production in Bangladesh: impact on farmers’ food security and poverty situation. Agric Food Secur 7:1–15CrossRefGoogle Scholar
  54. Uddin MT, Dhar AR, Rahman MH (2017) Improving farmers’ income and soil environmental quality through conservation agriculture practice in Bangladesh. Am J Agric Biol Sci 12(1):55–65CrossRefGoogle Scholar
  55. Uddin MT, Dhar AR, Hossain N (2018a) A socioeconomic study on farming practices and livelihood status of Haor farmers in Kishoreganj district: natural calamities perspective. Bangladesh J Ext Educ 30(1):27–42Google Scholar
  56. Uddin MT, Goswami A, Rahman MS, Dhar AR, Khan MA (2018b) Value chain of Pangas and Tilapia in Bangladesh. J Bangladesh Agric Univ 16(3):503–512CrossRefGoogle Scholar
  57. Uddin MT, Hossain N, Dhar AR (2019) Business Prospects and Challenges in Haor Areas of Bangladesh. J Bangladesh Agric Univ 17(1):65–72CrossRefGoogle Scholar
  58. UNB (2016) United News of Bangladesh. Water Management for Agricultural Development. The Daily Star. https://www.thedailystar.net/supplements/25th-anniversary-special-part-4/water-management-agricultural-development-211999
  59. UNB (2018) United News of Bangladesh. Water Saving Technology Vital to Lessening Pressure on Groundwater. The Independent. http://www.theindependentbd.com/arcprint/details/157450/2018-07-12
  60. UNP (2018) United news of Pakistan. alternate wetting drying: a novel technique to save water in flooded rice. The Weekly Technology Times. https://www.technologytimes.pk/alternate-wetting-drying-water-saving-flooded-rice/
  61. Uphoff N (2003) Higher yields with fewer external inputs? The system of rice intensification and potential contributions to agricultural sustainability. Int J Agric Sustain 1(1):38–50CrossRefGoogle Scholar
  62. Uphoff N (2004) System of rice intensification responds to 21st century needs. Rice Today. http://tatiek.lecture.ub.ac.id/files/2009/08/sri-3.pdf
  63. Wart JV, Kersebaum C, Peng S, Milner M, Cassman KG (2013) Estimating crop yield potential at regional to national scales. Field Crops Res 143:34–43CrossRefGoogle Scholar
  64. Wu X (1998) Development of water saving irrigation technique on Large Paddy Rice Area in Guangxi Region of China. International Commission for Irrigation and Drainage. http://www.icid.org/wat_xijin.pdf
  65. Yang WY (1965) Methods of farm management investigation for improving farm productivity. Food and Agriculture Organization of the United Nations, RomeGoogle Scholar
  66. Zhi M (2002) Water efficient irrigation and environmentally sustainable irrigated rice production in china. International Commission on Irrigation and Drainage. http://www.icid.org/wat_mao.pdf

Copyright information

© Springer-Verlag GmbH Germany, part of Springer Nature 2020

Authors and Affiliations

  1. 1.Department of Agricultural EconomicsBangladesh Agricultural UniversityMymensinghBangladesh

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