College of Mathematics and Statistics, Fujian Normal University, Fuzhou, 350007, Fujian, PR China.
College of Mathematics and Statistics, Fujian Normal University, Fuzhou, 350007, Fujian, PR China; Fujian Key Laboratory of Mathematical Analysis and Applications; Center of Applied Mathematics(FJNU), Fuzhou, 350007, Fujian, PR China.
Biosystems. 2024 May;239:105210. doi: 10.1016/j.biosystems.2024.105210. Epub 2024 Apr 8.
Most nutrient uptake problems are modeled by the convection-diffusion equation (CDE) abiding by Fick's law. Because nutrients needed by plants exist in the soil solution as a form of ions and the soil is a typical fractal structure of heterogeneity, it makes the solute transport appear anomalous diffusion in soil. Taking anomalous diffusion as a transport process, we propose time and space fractional nutrient uptake models based on the classic Nye-Tinker-Barber model. There does not appear apparent sub-diffusion of nitrate in the time fractional model until four months and the time fractional models are appropriate for describing long-term dynamics and slow sorption reaction; the space fractional model can capture super-diffusion in short term and it is suitable for describing nonlocal phenomena and daily variations driven by transpiration and metabolism; the anomalous diffusion more apparently appears near the root surface in the modeling simulation.
大多数养分吸收问题都是通过符合菲克定律的对流扩散方程(CDE)来建模的。由于植物所需的养分以离子的形式存在于土壤溶液中,而土壤是一种典型的分形异质性结构,这使得溶质在土壤中的传输呈现反常扩散。以反常扩散作为传输过程,我们基于经典的 Nye-Tinker-Barber 模型提出了时空分数阶养分吸收模型。在时间分数阶模型中,硝酸盐在四个月内没有明显的亚扩散,时间分数阶模型适合描述长期动力学和缓慢的吸附反应;空间分数阶模型可以在短期内捕捉到超扩散,适合描述由蒸腾和代谢驱动的非局部现象和日变化;在建模模拟中,反常扩散在根表面附近表现得更为明显。
