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Modeling the coupling processes of evapotranspiration and soil water balance in agroforestry systems

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  • Wang, Zikui
  • Wu, Yuhuan
  • Cao, Quan
  • Shen, Yuying
  • Zhang, Baoqing

Abstract

How evapotranspiration (ET) and its partitioning in agroforestry systems are influenced by canopy structure as well as soil water availability is not well explained. Modeling work was combined with field experiment in this study to investigate the interaction of ET and soil water conditions in an apple tree (Malus pumila M.) and cocksfoot (Dactylis glomerata L.) agroforestry. The experiment was conducted in 2016–2018 in an apple orchard at a spacing of 4 m × 4 m on the Loess Plateau of China. The three tested planting patterns were: monoculture apple tree with clean tillage (CT), agroforestry with 2.4-meter-wide cocksfoot strips between tree rows that harvested frequently to maintain a low coverage (LC), and agroforestry with cocksfoot of a greater coverage (GC). The multi-source ET model developed for intercropping system was improved by considering the effects of large height difference of different species in agroforestry on water vapor transporting resistances, then the improved ET model was combined with a soil water balance model to simulate ET partitioning. Soil water content in 0–200 cm layer, seasonal ET calculated with soil water balance model, and directly measured understorey ET were used to validate the model. Results showed that the root mean square error (NRMSE) for simulated soil water content ranged from 7.3% to 10.1%, and NRMSE for simulated total ET and understorey ET were only 3.9% and 4.2% respectively. Transpiration of apple tree in GC and LC was reduced by 21.3−32.5% and 12.3−24.2% after applying agroforestry, the reduction was mainly attributed to the decrease in soil water content. Planting cocksfoot also reduced soil evaporation by 21.5−27.6%, total ET in the agroforestry was only changed by − 4.9–6.7% compared to CT. Scenario simulation indicated that the negative effects of cocksfoot on apple tree transpiration linearly decreased with increase of the maximum LAI of apple tree and exponentially increased with the increase of strip width of cocksfoot. An 18-year simulation showed that GC and LC reduced the transpiration of apple tree by 7.3% and 2.1% respectively, but did not accelerate soil water depletion in the deep soil layers. Therefore, agroforestry with well managed understorey grain or cover crops is encouraged to be applied in our study area to increase the production and provide ecological services. Water transportation model developed in this study could also be used to evaluate water use and improve the design and management of other agroforestry systems.

Suggested Citation

  • Wang, Zikui & Wu, Yuhuan & Cao, Quan & Shen, Yuying & Zhang, Baoqing, 2021. "Modeling the coupling processes of evapotranspiration and soil water balance in agroforestry systems," Agricultural Water Management, Elsevier, vol. 250(C).
    • Handle: RePEc:eee:agiwat:v:250:y:2021:i:c:s0378377421001049
    DOI: 10.1016/j.agwat.2021.106839
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    References listed on IDEAS

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    1. Zhao, Peng & Li, Sien & Li, Fusheng & Du, Taisheng & Tong, Ling & Kang, Shaozhong, 2015. "Comparison of dual crop coefficient method and Shuttleworth–Wallace model in evapotranspiration partitioning in a vineyard of northwest China," Agricultural Water Management, Elsevier, vol. 160(C), pages 41-56.
    2. Hernandez, A.J. & Lacasta, C. & Pastor, J., 2005. "Effects of different management practices on soil conservation and soil water in a rainfed olive orchard," Agricultural Water Management, Elsevier, vol. 77(1-3), pages 232-248, August.
    3. Celette, Florian & Ripoche, Aude & Gary, Christian, 2010. "WaLIS--A simple model to simulate water partitioning in a crop association: The example of an intercropped vineyard," Agricultural Water Management, Elsevier, vol. 97(11), pages 1749-1759, November.
    4. Wang, Zikui & Cao, Quan & Shen, Yuying, 2019. "Modeling light availability for crop strips planted within apple orchard," Agricultural Systems, Elsevier, vol. 170(C), pages 28-38.
    5. Bai, Wei & Sun, Zhanxiang & Zheng, Jiaming & Du, Guijuan & Feng, Liangshan & Cai, Qian & Yang, Ning & Feng, Chen & Zhang, Zhe & Evers, Jochem B. & van der Werf, Wopke & Zhang, Lizhen, 2016. "Mixing trees and crops increases land and water use efficiencies in a semi-arid area," Agricultural Water Management, Elsevier, vol. 178(C), pages 281-290.
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    2. Lai, Xingfa & Yang, Xianlong & Wang, Zikui & Shen, Yuying & Ma, Longshuai, 2022. "Productivity and water use in forage-winter wheat cropping systems across variable precipitation gradients on the Loess Plateau of China," Agricultural Water Management, Elsevier, vol. 259(C).
    3. Chen, Zhixue & Wang, Guohui & Yang, Xianlong & Li, Zhenfeng & Shen, Yuying, 2023. "Water competition among the coexisting Platycladus orientalis, Prunus davidiana and Medicago sativa in a semi-arid agroforestry system," Agricultural Water Management, Elsevier, vol. 279(C).
    4. Marcos Vinicius Mansano Sarto & Wander Luis Barbosa Borges & Doglas Bassegio & Márcio Renato Nunes & Charles W. Rice & Ciro Antonio Rosolem, 2022. "Deep Soil Water Content and Forage Production in a Tropical Agroforestry System," Agriculture, MDPI, vol. 12(3), pages 1-13, March.

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