Influence of Irrigation Regime on Total Yield of Tomato Crop and Water Productivity under Drip Irrigation System

Journal of Soil Sciences and Agricultural Engineering Pub Date : 2024-07-15 DOI:10.21608/jssae.2024.298525.1234

Mohamed Salah Abd-El Baki, M. M. Ibrahim, S. E. M. El-Sayed, Nadia G. A. Daoud

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Abstract

Water scarcity remains a significant challenge for global agriculture. Deficit irrigation has emerged as a strategy to optimize water productivity without compromising crop yield. This study aimed to assess the impact of deficit irrigation on tomato yield and water productivity (WP). Two field experiments were conducted over consecutive seasons of 2022 and 2023 using drip irrigation. Three irrigation regimes were employed: 100% (T100), 75% (T75), and 50% (T50) of the full irrigation requirements. Crop stress indicators, including fresh biomass weight (FB), dry-biomass weight (DB), canopy water content (CWC), soil moisture content (SMC), and relative chlorophyll content (SPAD measures) were evaluated. The results showed that the highest values of FB, DB, CWC, SMC, and yield were achieved under T100, followed by T75, while the lowest values were observed at T50. The highest SPAD values were obtained under T75, followed by T100 and T50 for both seasons. The results further showed that the highest WP values were observed with T100 (27.37 kg/m 3 ), followed by T75 (25.96 kg/m 3 ). The lowest WP value was 21.58 kg/m 3 at T50. The application of T75 and T50 led to saving 22.29% and 44.57% of the irrigation water applied compared to T100 in both seasons, respectively. In conclusion, this study proves that applying moderate deficit irrigation at T75 is considered to be a feasible technique for tomato production.

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滴灌系统下灌溉制度对番茄总产量和水分生产率的影响

缺水仍然是全球农业面临的重大挑战。缺水灌溉已成为在不影响作物产量的前提下优化水分生产率的一种策略。本研究旨在评估亏缺灌溉对番茄产量和水分生产率（WP）的影响。在 2022 年和 2023 年连续两季进行了滴灌田间试验。采用了三种灌溉制度：100%（T100）、75%（T75）和 50%（T50）的全灌溉要求。对作物胁迫指标进行了评估，包括新鲜生物量重量（FB）、干生物量重量（DB）、冠层含水量（CWC）、土壤含水量（SMC）和相对叶绿素含量（SPAD测量值）。结果表明，在 T100 条件下，FB、DB、CWC、SMC 和产量值最高，其次是 T75，而在 T50 条件下，FB、DB、CWC、SMC 和产量值最低。两季中，T75 的 SPAD 值最高，其次是 T100 和 T50。结果还显示，T100 的 WP 值最高（27.37 kg/m 3 ），其次是 T75（25.96 kg/m 3 ）。T50 的可湿性粉剂值最低，为 21.58 公斤/米 3。与 T100 相比，施用 T75 和 T50 可分别节约两季灌溉用水的 22.29% 和 44.57%。总之，本研究证明，在 T75 温度下进行适度亏缺灌溉是番茄生产的可行技术。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Soil Sciences and Agricultural Engineering

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