维管植物韧皮部液流和碳水化合物运输:一个通用的表面模型

2012 IEEE 4th International Symposium on Plant Growth Modeling, Simulation, Visualization and Applications Pub Date : 2012-10-01 DOI:10.1109/PMA.2012.6524854

Damien Sellier, J. Harrington

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引用次数: 0

摘要

植物叶片产生的碳水化合物通过韧皮部途径分布在整个生物体中。了解韧皮部运输如何运作对于模拟树木生长活动和碳分配模式至关重要。与m nch的假设一致，我们将韧皮部汁液运动建模为压力流动。这是一个单溶质(蔗糖)模型。它通过在代表韧皮部的三角形表面上进行有限元分析来解决类似扩散的方程。在这项研究中，我们证明了表面模型与表示像树这样的建筑复杂结构是兼容的。该模型还考虑了晶粒取向对易位的影响。模拟树枝连接处的液流突出表明，碳水化合物主要沿着韧皮部纤维的纵向方向移动。然而，在目前对植物同化物运输的理解中，侧向运输仍然是一个主要的未知数。

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Phloem sap flow and carbohydrate transport in vascular plants: A generic surface model

Plant leaves produce carbohydrates that are distributed throughout the organism via the phloem pathway. Understanding how phloem transport operates is essential to simulate patterns of growth activity and carbon allocation within trees. In agreement with Münch's hypothesis, we model phloem sap motion as a pressure flow. This is a single-solute (sucrose) model. It solves diffusion-like equations using finite element analysis on a triangulated surface that represents the phloem. In this study, we show that the surface model is compatible with representing architecturally complex structures like trees. The model also takes into account the effect of grain orientation on translocation. Simulating sap flow at a branchstem junction highlights that carbohydrates move dominantly along the longitudinal direction of phloem fibres. However, lateral transport remains a major unknown in the current understanding of assimilate transport in plants.

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2012 IEEE 4th International Symposium on Plant Growth Modeling, Simulation, Visualization and Applications

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