Water Supply (Jan 2022)

Changes in soil-water content and heat transport under different simulated systems of drip irrigation in gravel-mulched fields

  • Wenju Zhao,
  • Yali Wang,
  • Junhong Hu,
  • Zongli Li,
  • Yingdong Zhao,
  • Guihua Qi

DOI
https://doi.org/10.2166/ws.2021.262
Journal volume & issue
Vol. 22, no. 1
pp. 452 – 461

Abstract

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Gravel mulching is an ancient mulching system with a history of more than 300 years in China. To explore the changes of soil-water content (SWC) and heat transport in watermelon gravel-mulched fields under drip irrigation, we simulated three irrigation quotas (W1, 180 m3/hm2; W2, 270 m3/hm2; and W3, 360 m3/hm2) and three irrigation frequencies (F1, three times; F2, six times; and F3, nine times) based on HYDRUS-2D. The results indicated that peak SWC increased with irrigation quota. The range of fluctuation of SWC decreased as irrigation frequency increased. The temperature of the 0–40 cm soil layer varied with air temperature, but the range of fluctuation decreased with depth. Irrigation affected the distribution of soil water, increased soil heat capacity, and reduced the impact of air temperature on soil temperature, thus delaying the impact of air temperature on soil temperature. High-frequency drip irrigation could therefore effectively improve SWC, reduce water stress during the period of watermelon growth, and effectively delay the effect of air temperature on soil temperature, providing a theoretical basis for developing reasonable irrigation strategies and regulating soil water and heat in gravel-mulched fields. HIGHLIGHTS Irrigation affects the distribution of soil moisture and the change of soil temperature.; Under the same irrigation quota, a high-frequency irrigation system is beneficial for increasing the water content of the soil.; High-frequency drip irrigation can effectively reduce the impact of air temperature on the temperature of the soil cultivated layer.;

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