Experimental Evaluation of Irrigation Methods for Yield, Water Productivity, and Economics of Paddy-Wheat Cropping System under Conservation Agriculture

Arpna Bajpai; Arun Kaushal; Harminder Singh Sidhu; Anchal Kumar Jain

doi:10.52151/jae2023601.1799

Authors

Arpna Bajpai Department of Agricultural Engineering, Krishi Vigyan Kendra, Kasturbagram, Indore Author
Arun Kaushal Department of Soil and Water Engineering, Punjab Agricultural University, Ludhiana Author
Harminder Singh Sidhu College of Agricultural Engineering & Technology, Punjab Agricultural University, Ludhiana Author
Anchal Kumar Jain Department of Soil and Water Engineering, Punjab Agricultural University, Ludhiana Author

DOI:

https://doi.org/10.52151/jae2023601.1799

Keywords:

Conservation agriculture, paddy-wheat cropping system, soil moisture distribution, sub-surface drip, water productivity

Abstract

Irrigation methods have critical role in increasing the water productivity and crop production under paddy-wheat cropping systems. An experiment was carried out at Ludhiana, Punjab, India, in a randomized block design with eight treatments on drip and flood irrigation systems under conventional and conservation agricultural practices. Under conservation agriculture practice, drip irrigation had six treatments with different combinations of dripline spacing × emitter spacing × dripline depth as 675 × 300 × 0 mm (T1), 450 × 400 × 0 mm (T2), 675 × 300 × 150 mm (T3), 450 × 400 × 150 mm (T4), 675 × 300 × 200 mm (T5), 450 × 400 × 200 mm (T6). The treatments on conventional flood irrigation method included crop cultivation under farmer’s practice (T7) and under conservation agriculture practice (T8). The treatment T4 recorded significantly higher grain yield of wheat (6.522 t.ha-1) and paddy (8.178 t.ha-1) and water productivity (3.73, 1.20 kg.m-3, respectively. In the root zone of both wheat and paddy crops, the drip irrigation systems recorded lowest soil moisture variation within 0-450 mm soil depth under treatment T4 (4.33% to 9.77%), while it was highest under T7 (10.38% to 40.41%). The treatment T4 also showed water saving of 55.3% over the conventional flood irrigation method under paddy-wheat cropping system. In economic terms, the treatment T4 performed better with a benefit-cost ratio of 3.15 under the condition that 95% subsidy is availed on cost of drip irrigation system.

Author Biographies

Arpna Bajpai, Department of Agricultural Engineering, Krishi Vigyan Kendra, Kasturbagram, Indore

Subject Matter Specialist,
Arun Kaushal, Department of Soil and Water Engineering, Punjab Agricultural University, Ludhiana

Professor,
Harminder Singh Sidhu, College of Agricultural Engineering & Technology, Punjab Agricultural University, Ludhiana

Dean,
Anchal Kumar Jain, Department of Soil and Water Engineering, Punjab Agricultural University, Ludhiana

Professor (Retired),

References

Anon.. 2017. Package of Practices for Rabi Crops. Punjab Agricultural University, Ludhiana, pp: 25.

Anon. 2018. Package of Practices for kharif Crops. Punjab Agricultural University, Ludhiana, .

Anon. 2022. Fourth Advance Estimates of Production of Food grains for 2021-22. Ministry of Agriculture and Farmers Welfare, Government of India, New Delhi, pp: 2. Available at: https://static.pib.gov.in/WriteReadData/specificdocs/documents/2022/aug/doc202281792701.pdf (accessed on 6 March 2022).

Assefa T; Jha M; Reyes M; Worqlul A W. 2018. Modeling the impacts of conservation agriculture with a drip irrigation system on the hydrology and water management in Sub-saharan Africa. Sustainability, 10, 2-19.

Bajpai A; Kaushal A. 2020. Soil moisture distribution pattern under trickle irrigation: A review. Water Supply, 20, 761-772.

CGWB. 2020. Annual Report 2018-19. Department of Water Resources, River Development & Ganga Rejuvenation, Central Ground Water Board, Ministry of Jal Shakti, Faridabad, pp: 90. Available at http://cgwb. gov.in/Annual-Reports/ANNUAL%20REPORT%20CGWB%202018-19_final.pdf (accessed on 6 March 2022).

Dass A; Chandra S. 2013. Irrigation, spacing and cultivar effects on net photosynthetic rate, dry matter partitioning and productivity of rice under system of rice intensification in molli sols of northern India. Explor. Agric., 49, 504-523.

Haibing He; Fuyu M; Yang R; Chen L; Jia B; Cui J; Fan H; Wang X; Li L. 2013. Rice performance and water use efficiency under plastic mulching with drip irrigation. PLos. One., 8, 1-15.

Hargreaves G H; Allen R G. 1994. History and evaluation of Hargreaves evapotranspiration equation. J. Irrig. Drain. Eng., 129, 53-63.

Jansson P E; Karlberg L. 2001. Coupled Heat and Mass Transfer Model for Soil-plant atmosphere Systems. Royal Institute of Technology, Department of Civil and Environmental Engineering, Stockholm, England, pp: 321.

Jat H S; Sharma P C; Datta A; Choudhary M; Kakraliya S K; Singh Y; Sidhu H S; Gerard B; Jat M L. 2019. Re-designing irrigated intensive cereal systems through bundling precision agronomic innovations for transitioning towards agricultural sustainability in North-West India. Sci. Rep., 9, 1-14.

Khan J. 2014. Studies on fertilizer movement under drip fertigated guava. Unpublished Ph.D. Dissertation, Punjab Agricultural University, Ludhiana, Punjab.

Kharrou M H; Salah R; Ahmed C; Benoit D; Vincent S; Michel L; Lahcen O; Lionel J. 2011. Water use efficiency and yield of winter wheat under efferent irrigation regimes in a semi-arid region. Agric. Sci., 2, 273-282.

Lokhande J N; Deshmukh M M; Krishna B; Wadatkar S B. 2019. Maximizing yield and water use efficiency of wheat crop using drip irrigation systems. Int. J. Curr. Microbiol. Appl. Sci., 8, 2647-2655.

Mboyerwa P A; Kibebew K T; Mtakwa P W; Aschalew A. 2021. Evaluation of growth, yield and water productivity of paddy with water-saving irrigation and optimization of nitrogen fertilization. Agron., 1629, 1-23.

Patel R; Rank H D. 2022. Water use efficiency of wheat under different irrigation regimes using high discharge drip irrigation system. Agric. Eng. Today, 44 (2), 19-31.

Ramulu V; Praveen R; Uma D; Kumar A; Radhika. 2016. Evaluation of drip irrigation and fertigation levels in aerobic paddy for higher water productivity. 2nd World Irrigation Forum (WIF2) 6-8 November 2016, Chiang Mai, Thailand, 1-10.

Rao K V R; Bajpai A; Gangwar S; Chourasia L; Soni K. 2016. Maximizing water productivity of wheat crop by adopting drip irrigation. Res. Crops, 17, 163-168.

Rao K V R; Gangwar S; Keshri R; Chourasia L; Bajpai A; Soni K. 2017. Effects of drip irrigation system for enhancing paddy (oryza sativa l.) yield under system of paddy intensification management. Appl. Ecol. Environ. Res., 15, 487-495.

Ritchie J T. 1972. Model for predicting evaporation from a row crop with incomplete cover. Water Resour. Res., 8, 1204-1213.

Saxena C K; Gupta S K; Purohit R C; Bhakar S R; Upadhyay B. 2013. Performance of okra under drip irrigation with saline water. J. Agric. Eng., 50 (4), 72-75.

Saxena C K; Singh R; Pyasi S K; Mekale A K. 2018. Evaluation of movement of wetting front under surface point source of drip irrigation in Vertisols. J. Agric. Eng., 55 (2), 61-67.

Schaap M G; Leij F J; Van Genuchten M T. 2001. ROSETTA: A computer program for estimating soil hydraulic properties with hierarchical pedotransfer functions. J. Hydrol., 251, 163-176.

Sharda R; Mahajan G; Siag M; Singh A; Chauhan B S. 2017. Performance of drip-irrigated dry-seeded paddy (Oryza sativa L.) in South Asia. Paddy Water Environ., 15, 93-100.

Sharma N; Bhardwaj A K; Soman P; Pandiaraj T; Labh B K. 2021. Enhancing crop and water productivity of wheat in different establishment methods in Haryana: An on-farm study. Int. J. Agric. Sci., 13, 10986-10990.

Sharma P. 2015. Water productivity of drip fertigated okra. Unpublished M.Tech. Thesis, Punjab Agricultural University, Ludhiana, Punjab.

Sharma V; Singh Y P; Singh P K. 2017. Estimation of crop water requirement for summer paddy under drip irrigation system in Tarai region of Uttarakhand. Int. J. Technol. Res. Appl., 5, 8-24.

Sidhu H S; Jat M L; Singh Y; Sidhu R K; Gupta N; Singh P; Singh P; Jat H S; Gerard B. 2019. Sub-surface drip fertigation with conservation agriculture in a paddy-wheat system: A breakthrough for addressing water and nitrogen use efficiency. Agric. Water Manage., 216, 273–83.

Simunek J; Genuchten M T V; Šejna M. 2012. HYDRUS technical manual. version 2.0. PC-Progress, Prague, Czech Republic, pp: 6.

Singh K; Singh P; Singh M; Mishra S K; Iqbal R; Ibrahim A A; Rahman M H; Sabagh A E. 2022. Sub-surface drip fertigation improves seed cotton yield and monetary returns. Front. Plant Sci., 13, 1-18.

Surendran U; Raja P; Jayakumar M; Subramoniam S R. 2021. Use of efficient water saving techniques for production of paddy in India under climate change scenario: A critical review. J. Cleaner Production., 309, 1-7.

Tilahun Z M. 2019. Effect of row spacing and nitrogen fertilizer levels on yield and yield components of paddy varieties. World Sci. News, 116, 180-193.

Umair M; Hussain T; Jiang H; Ahmad A; Yao J; Qi Y; Zhang Y; Min L; Shen Y. 2019. Water-saving potential of sub-surface sub-surface drip irrigation for winter wheat. Sustainability, 11, 1-15.

USDA. 2017. Soil Survey Manual, By Soil Science Division Staff, United States Department of Agriculture Handbook No 18, U.S. Department of Agriculture, Washington, D.C., pp: 585.

Wang F X; Kang Y; Liu S P. 2006. Effects of drip irrigation frequency on soil wetting pattern and potato growth in North China Plain. Agric. Water. Manage., 79, 248-264.

Zhang X Y; Chen S Y; Liu M Y; Pei D; Sun H Y. 2005. Improved water use efficiency associated with cultivars and agronomic management in the North China Plain. Agron. J., 97, 783-790.