Improving water productivity of sprinkler-irrigated cumin through deficit irrigation in arid areas

doi:10.1007/s40333-025-0080-0

Journal of Arid Land

2025, Vol. 17

Issue (6): 791-807 DOI: 10.1007/s40333-025-0080-0 CSTR: 32276.14.JAL.02500800

Review article

Improving water productivity of sprinkler-irrigated cumin through deficit irrigation in arid areas

Hari Mohan MEENA^*(

), Deepesh MACHIWAL, Priyabrata SANTRA, Vandita KUMARI, Saurabh SWAMI

Division of Natural Resources, Indian Council of Agricultural Research (ICAR)-Central Arid Zone Research Institute (CAZRI), Jodhpur 342003, India

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Abstract

Integrating sprinkler with deficit irrigation system is a new approach to improve crop water productivity and ensure water and food security in arid areas of India. This study undertook a field experiment of sprinkler-irrigated cumin (variety GC-4) with a mini-lysimeter setup at an experimental research farm in Jodhpur, India during 2019-2022. Four irrigation treatments T₁, T₂, T₃, and T₄ were designed at irrigation water/cumulative pan evaporation (IW/CPE) of 1.0, 0.8, 0.6, and 0.4, respectively, with three replications. Daily actual crop evapotranspiration (ET_c) was recorded and weekly soil moisture was monitored over the crop growth period. Quantities of applied water and drainage from mini-lysimeters were also measured at every irrigation event. Yield of cumin was recorded at crop maturity. Furthermore, change in farmer's net income from 1-hm² land was computed based on the cost of applying irrigation water and considering yield variations among the treatments. Results indicated the highest mean seasonal actual ET_c (371.7 mm) and cumin yield (952.47 kg/hm²) under T₁ (with full irrigation). Under T₂, T₃, and T₄, the seasonal actual ET_c decreased by 10.4%, 27.6%, and 41.3%, respectively, while yield declined by 5.0%, 28.4%, and 50.8%, respectively, as compared to the values under T₁. Furthermore, crop water productivity of 0.272 (±0.068) kg/m³ under T₂ was found relatively higher in comparison to other irrigation treatments, indicating that T₂ can achieve improved water productivity of cumin in arid areas at an optimum level of deficit irrigation. The results of cost-economics indicated that positive change in farmer's net income from 1-hm² land was 108.82 USD under T₂, while T₃ and T₄ showed net losses of 5.33 and 209.67 USD, respectively. Moreover, value of yield response factor and ratio of relative yield reductions to relative ET_c deficits were found to be less than 1.00 under T₂ (0.48), and more than 1.00 under T₃ (1.07) and T₄ (1.23). This finding further supports that T₂ shows the optimized level of deficit irrigation that saves 20.0% of water with sacrificing 5.0% yield in the arid areas of India. Findings of this study provide useful strategies to save irrigation water, bring additional area under irrigation, and improve crop water productivity in India and other similar arid areas in the world.

Key words： cumin crop crop water productivity crop evapotranspiration deficit irrigation mini-sprinkler irrigation yield response factor

Received: 23 October 2024 Published: 30 June 2025

Corresponding Authors: ^*Hari Mohan MEENA (E-mail: Hari.Meena5@icar.gov.in; hmmeena82@gmail.com)

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	Hari Mohan MEENA
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	Vandita KUMARI
	Saurabh SWAMI

Cite this article:

Hari Mohan MEENA, Deepesh MACHIWAL, Priyabrata SANTRA, Vandita KUMARI, Saurabh SWAMI. Improving water productivity of sprinkler-irrigated cumin through deficit irrigation in arid areas. Journal of Arid Land, 2025, 17(6): 791-807.

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http://jal.xjegi.com/10.1007/s40333-025-0080-0 OR http://jal.xjegi.com/Y2025/V17/I6/791

Table 1 Long-term means of climate variables during 1991-2020 and short-term climate variable values in the study years 2019, 2020, 2021, and 2022) for the five months of the crop growth period (November-March) at the experimental site

Table 2 Soil physical properties of the experimental site

Fig. 1 Soil moisture dynamics under different irrigation treatments (T₁-T₄) during the crop growth period of 2019-2021 (a1-a4), 2020-2021 (b1-b4), and 2021-2022 (c1-c4). T₁, T₂, T₃, and T₄ were designed at irrigation water/cumulative pan evaporation (IW/CPE) of 1.0, 0.8, 0.6, and 0.4, respectively. Error bars mean standard errors.

Fig. 2 Daily actual crop evapotranspiration (ET_c) dynamics under different irrigation treatments (T₁, T₂, T₃, and T₄) during the crop growth period of 2019-2021 (a1-a4), 2020-2021 (b1-b4), and 2021-2022 (c1-c4). OPE, open pan evaporation.

Table 3 Seasonal actual ET_c, crop yield, and crop water productivity under four irrigation treatments

Table 4 Costs and benefits under deficit irrigation along with change in farmer's net income from 1-hm² land

Fig. 3 Relationship between relative deficit in actual ET_c (1-(ET_a/ET_m)) and relative reduction in crop yield (1-(Y_a/Y_m)) indicating the overall crop yield response factor. ET_a is actual ET_c under three deficit irrigation treatments (T₂, T₃, and T₄); ET_m is the maximum actual ET_c under T₁; Y_a is the actual crop yield obtained under three deficit irrigation treatments (T₂, T₃, and T₄); Y_m is the maximum crop yield obtained under T₁.

Table 5 Crop yield response factor under different irrigation treatments (averaged over three crop growth periods)

Fig. 4 Scatter diagram between crop yield with actual ET_c (a) and amount of applied irrigation water (b) during the three crop growth periods

Fig. 5 Scatter diagram between actual ET_c and amount of applied irrigation water during the entire crop growth period


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