Study on the Synergistic Regulation Model for <i>Lycium barbarum</i> Berries Under Integrated Irrigation and Fertigation in Northwest Arid Regions

Study on the Synergistic Regulation Model for <i>Lycium barbarum</i> Berries Under Integrated Irrigation and Fertigation in Northwest Arid Regions

Water resources are fundamental to economic and social development. Improving agricultural water-use efficiency is essential for alleviating water scarcity, ensuring food security, and fostering sustainable growth. This study examines the effects of irrigation levels (severe water deficit, W0: 45–55...

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Bibliographic Details
Main Authors: Yanlin Ma, Huile Lv, Yanbiao Wang, Yayu Wang, Minhua Yin, Yanxia Kang, Guangping Qi, Rong Zhang, Jinwen Wang, Junxian Chen
Format: Article
Language:English
Published: MDPI AG 2024-12-01
Series:Agronomy
Subjects:
<i>Lycium barbarum</i>
water–fertilizer integration
soil environment
regulation model
Online Access:https://www.mdpi.com/2073-4395/15/1/73
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Summary:Water resources are fundamental to economic and social development. Improving agricultural water-use efficiency is essential for alleviating water scarcity, ensuring food security, and fostering sustainable growth. This study examines the effects of irrigation levels (severe water deficit, W0: 45–55% <i>θ<sub>FC</sub></i>; moderate water deficit, W1: 55–65% <i>θ<sub>FC</sub></i>; mild water deficit, W2: 65–75% <i>θ<sub>FC</sub></i>; full irrigation, W3: 75–85% <i>θ<sub>FC</sub></i>) and nitrogen application rates (N0: 0 kg·hm<sup>−2</sup>, N1: 150 kg·hm<sup>−2</sup>, N2: 300 kg·hm<sup>−2</sup>, N3: 450 kg·hm<sup>−2</sup>) on soil environment, crop yield, and water–nitrogen use efficiencies in <i>Lycium barbarum</i> under integrated water–fertilizer drip irrigation. The coordinated application of water and nitrogen significantly influenced yield and efficiencies (<i>p</i> < 0.05) by modifying rhizosphere conditions such as soil moisture, temperature, salinity, and enzyme activities. Soil temperature increased with nitrogen application (N1 > N2 > N0 > N3), with N1 raising soil temperature by 4.98–8.02% compared to N0, N2, and N3. Electrical conductivity was lowest under N0, showing a 7.53–18.74% reduction compared to N1, N2, and N3. Urease activity peaked under N3 (31.84–96.78% higher than other treatments), while alkaline phosphatase and catalase activities varied across treatments. The yield was highest under N2, at 6.79–41.31% higher than other nitrogen treatments. Water use efficiency (WUE), growth use efficiency (GUE), and nitrogen agronomic efficiency (NAE) peaked under N2, while nitrogen use efficiency (NUE) decreased with higher nitrogen rates. Among irrigation levels, W0 showed the highest soil temperature, while W3 exhibited the lowest conductivity in the 0–40 cm layer. W2 had the highest soil enzyme activities, yielding 4.41–42.86% more than other levels, with maximum efficiencies for WUE, GUE, NUE, and NAE. The combination of mild water deficit (65–75% <i>θ<sub>FC</sub></i>) and 300 kg·hm<sup>−2</sup> nitrogen application (W2N2) resulted in the highest yield (2701.78 kg·hm<sup>−2</sup>). This study provides key insights for implementing integrated drip irrigation in northwest China’s arid regions.
ISSN:2073-4395

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