Hydrological trends and agricultural water footprint in the Pennaiyar basin, Tamil Nadu

R A Anto; J Ramachandran; R Chandrasekaran R; V Arunkumar; S Manickam

doi:10.14719/pst.10637

Research Articles

Vol. 12 No. sp3 (2025): Advances in Plant Health Improvement for Sustainable Agriculture

Hydrological trends and agricultural water footprint in the Pennaiyar basin, Tamil Nadu

Anto Rashwin A^▸^▾
Ramachandran J^▸^▾
Chandrasekaran R^▸^▾
Arunkumar V^▸^▾
Manickam S^▸^▾

DOI: https://doi.org/10.14719/pst.10637
Submitted: 14 July 2025
Published: 08-12-2025

Abstract

India is currently facing one of its biggest challenges - the world’s worst water crisis. With only 2.5 % of India’s water resources, Tamil Nadu's water demand is rising due to increasing population, rapid urbanisation, variability in rainfall patterns and climate change, apart from agricultural water demand. In this context, the present study aims to assess the hydrological behavior of the Pennaiyar river basin located in the eastern part of Tamil Nadu, India. The assessment includes spatial and temporal analysis of rainfall and evapotranspiration (ET), dynamic evaluation of groundwater status and estimation of crop water footprint (WFP) for major crops in the basin. Results revealed that the average annual rainfall in the Pennaiyar river basin is approximately 927 mm. Seasonal rainfall distribution was 15 % in summer, 43 % during the southwest monsoon, 34 % during the northeast monsoon and 8 % in winter. Using the Hargreaves-Samani model, reference evapotranspiration (ET0) was found to range from 3.5 mm/day to 6.4 mm/day. The green WFP for paddy, maize, groundnut and sugarcane was 534 m³/t, 318 m³/t, 980 m³/t and 41 m³/t respectively. Similarly, the blue WFP for these crops was 500 m³/t, 177 m³/t, 592 m³/t and 54 m³/t respectively. The categorization of groundwater firkas (unit of Taluk) (2020, 2022 and 2023) in the Pennaiyar basin was done as over-exploited, critical, semi-critical and safe. In 2023, it was observed that there were 110 over-exploited firkas, 22 critical firkas, 61 semi-critical firkas and 63 safe firkas. The study emphasizes sustainable water management strategies for the Pennaiyar basin.

References

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28. Rajan D, Vijayalakshmi M, Nagamani K. Estimation of evapotranspiration using field measurements and modelling techniques on paddy crop water requirements in Kancheepuram District, Tamil Nadu, India. Water Util J. 2018;18:51–60.
29. Vanham D, Mekonnen M, Hoekstra A. Treenuts and groundnuts in the EAT-Lancet reference diet: concerns regarding sustainable water use. Glob Food Secur. 2020;24:1–7. https://doi.org/10.1016/j.gfs.2020.100357

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Keywords

evapotranspiration
groundwater
rainfall
spatio-temporal analysis
sustainability
water footprint

How to Cite

Anto RA, Ramachandran J, Chandrasekaran R R, Arunkumar V, Manickam S. Hydrological trends and agricultural water footprint in the Pennaiyar basin, Tamil Nadu. Plant Sci. Today [Internet]. 2025 Dec. 8 [cited 2026 Apr. 15];12(sp3). Available from: https://horizonepublishing.com/journals/index.php/PST/article/view/10637

This work is licensed under a Creative Commons Attribution 4.0 International License.

[1] 1. Kufeoglu S. SDG-6 Clean water and sanitation. Emerging technologies, value creation for sustainable development [e-book]. Springer Publications. 2022. https://doi.org/10.1007/978-3-031-07127-0_8

[2] 2. Surendran U, Sandeep O, Mammen G, Joseph EJ. A Novel technique of magnetic treatment of saline and hard water for irrigation and its impact on cowpea growth and water properties. Int J Agric Environ Biotechnol. 2013;6:85–92.

[3] 3. Bal SK, Chandran MAS, Madhavan SV, Rao AVMS, Manikandan N, Praveen Kumar R, et al. Water demand in maize is projected to decrease under changing climate in India. Sustainability. 2022;14(3):1419. https://doi.org/10.3390/su14031419

[4] 4. Mukherjee J, Bal SK, Singh G, Bhattacharya BK, Singh H, Kaur P. Surface energy fluxes in wheat (Triticum aestivum L.) under irrigated ecosystem. J Agrometeorol. 2012;14:16–20. https://doi.org/10.54386/jam.v14i1.1372

[5] 5. Tabari H. Climate change impact on flood and extreme precipitation increases with water availability. Sci Rep. 2020;10:13768. https://doi.org/10.1038/s41598-020-70816-2

[6] 6. Mehta P, Jangra MS, Bhardwaj SK, Paul S. Variability and time series trend analysis of rainfall in the mid-hill sub humid zone: a case study of Nauni. Environ Sci Pollut Res. 2022;29:80466–76. https://doi.org/10.1007/s11356-022-21507-0

[7] 7. Raviraj A, Thiyagarajan G, Ramachandran J, Panneerselvam S. Temporal variability in the precipitation concentration at Salem district of Tamil Nadu. Madras Agric J. 2020;107:226-29. https://doi.org/10.29321/MAJ.2020.000373

[8] 8. Tyagi NK, Sharma DK, Luthra SK. Determination of evapotranspiration and crop coefficients of rice and sunflower with lysimeter. Agric Water Manag. 2000;45:41–54. https://doi.org/10.1016/S0378-3774(99)00071-2

[9] 9. Mekonen B, Moges M, Gelagl D. Innovative irrigation water-saving strategies to improve water and yield productivity of onions. Int J Res Agric Sci. 2022;9:2348–3997.

[10] 10. Hoekstra AY, Hung PQ. Virtual water trade: A quantification of virtual water flows between nations in relation to international crop trade. Value Water Res Rep. The Netherlands. 2002.

[11] 11. Mali SS, Singh DK, Sarangi A, Khanna M, Parihar SS. Assessment of water footprints in Betwa river basin under limited data availability. J Agric Eng. 2019;56:60-73. https://doi.org/10.52151/jae2018551.1684.

[12] 12. Mali SS, Singh DK, Sarangi A, Khanna M, Parihar SS, Das DK. Variability mapping of crop evapotranspiration for water footprint assessment at basin level. Indian J Soil Conserv. 2015; 43(1): 255-59.

[13] 13. Ramachandran J, Lalitha R, Vallal Kannan S, Sivasubramanian K. Assessment of water footprint based on estimated crop evapotranspiration for paddy, sugarcane and banana under semi-arid climate. Environ Conserv J. 2022;23(1&2):302-08. https://doi.org/10.36953/ECJ.021805-2121

[14] 14. Ramachandran J, Lalitha R, Vallal Kannan S, Sivasubramanian K. Assessment of crop water footprint for different varieties of groundnut (Arachis hypogaea). Ind J Agric Res. 2021;1-6. https://doi.org/10.18805/IJARe.A-5831

[15] 15. Banerjee C, Kumar DN. Assessment of surface water storage trends for increasing groundwater areas in India. J Hydrol. 2018;562:780–88. https://doi.org/10.1016/j.jhydrol.2018.05.052

[16] 16. Ponnuchakkammal P, Ramachandran J, Raviraj A. Comparative analysis of rainfall occurrence and groundwater level fluctuations in Theni district of Tamil Nadu. Madras Agric J. 2020;107:92-96. https://doi.org/10.29321/MAJ 2020.000337

[17] 17. Ramachandran J, Lalitha R, Vallal Kannan S. Estimation of site-specific crop coefficients for major crops of Lalgudi block in Tamil Nadu using remote sensing based algorithms. J Agric Eng. 2021;58(1):62–72. https://doi.org/10.52151/jae2021581.1735

[18] 18. Raviraj A, Ramachandran J, Kaushal N, Mishra A. Simple water balance model and crop water demand at different spatial and temporal scales in Periya Pallam catchment of upper Bhavani basin, Tamil Nadu. Environ Conserv J. 2021;22(3):217–24. https://doi.org/10.36953/ECJ.2021.22326

[19] 19. Saranya T, Saravanan S. Groundwater potential zone mapping using analytical hierarchy process (AHP) and GIS for Kancheepuram District, Tamil Nadu, India. Model Earth Syst Environ. 2020. https://doi.org/10.1007/s40808-020-00744-7

[20] 20. Manivannan S, Thilagam VK, Yaligar R, Manoj KN. Crop planning using innovative trend analysis of 62-years rainfall data. Ind J Agric Sci. 2024;94(7):774–79. https://doi.org/10.56093/ijas.v94i6.145980

[21] 21. Janarth S, Jagadeeswaran R, Pazhanivelan S, Kannan B, Ragunath KP, Sathiyamoorthy NK. Drought monitoring over the Indian state of Tamil Nadu using multitudinous standardized precipitation evapotranspiration index. Plant Sci Today. 2024;11(4):106–15. https://doi.org/10.14719/pst.4653

[22] 22. Muthiah M, Sivarajan S, Madasamy N, Natarajan A, Ayyavoo R. Exploring short- and long-term meteorological drought parameters in the Vaippar Basin of Southern India. Sci Rep. 2024;14(1):13428. https://doi.org/10.1038/s41598-024-62095-y

[23] 23. Allen RG, Pereira LS, Raes D, Smith M. Crop evapotranspiration: guidelines for computing crop water requirements. Rome: Food and Agriculture Organization. 1998.

[24] 24. Balu A, Ramasamy S, Sankar G. Assessment of climate change impact on hydrological components of Ponnaiyar river basin, Tamil Nadu using CMIP6 models. J Water Clim Change. 2023;14. https://doi.org/10.2166/wcc.2023.354

[25] 25. Mohan Kumar S, Geethalakshmi V, Ramanathan S, Senthil A, Senthilraja K, Bhuvaneswari K, et al. Rainfall spatial-temporal variability and trends in the Thamirabharani River Basin, India: implications for agricultural planning and water management. Sustainability. 2022;14(22):14948. https://doi.org/10.3390/su142214948

[26] 26. Marumbwa FM, Cho MA, Chirwa PW. Analysis of spatio-temporal rainfall trends across southern African biomes between 1981 and 2016. Phys Chem Earth. 2019;114:102808. https://doi.org/10.1016/j.pce.2019.10.004

[27] 27. Venkatesh M, Vidhyavathi A, Suresh Kumar D, Raviraj A, Duraisamy MR. Quantifying water use efficiency in paddy production for different regions of Thenpennaiyaru River Basin of Tamil Nadu. J Exp Agric Int. 2022;44(10):79–89. https://doi.org/10.9734/jeai/2022/v44i1030881

[28] 28. Rajan D, Vijayalakshmi M, Nagamani K. Estimation of evapotranspiration using field measurements and modelling techniques on paddy crop water requirements in Kancheepuram District, Tamil Nadu, India. Water Util J. 2018;18:51–60.

[29] 29. Vanham D, Mekonnen M, Hoekstra A. Treenuts and groundnuts in the EAT-Lancet reference diet: concerns regarding sustainable water use. Glob Food Secur. 2020;24:1–7. https://doi.org/10.1016/j.gfs.2020.100357