Collaborative Research: Comparative Hydraulic Architecture; an Analysis of Transport Efficiency and Mechanical Constraints

合作研究：比较水利建筑；

• 批准号: 0544470
• 负责人: Frederick Meinzer
• 金额: --
• 依托单位: Oregon State University
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-03-15 至 2010-02-28
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0544470&HistoricalAwards=false
• 关键词: Collaborative; Research; Comparative; Hydraulic; Architecture

The need for plants to acquire CO2 for photosynthesis results in the passive loss of large amounts of water vapor from their leaves, which must be continuously replaced by the xylem, a transport tissue consisting of thousands of dead, hollow conduits running from the roots to the leaves. Hydraulic architecture determines the capacity and efficiency with which the xylem is able to supply water to the leaves, and thus limits the rate at which plants can gain carbon and grow. In many woody plants, the xylem conduits serve dual functions of water transport and mechanical support, leading to a partial sacrifice of hydraulic efficiency for mechanical stability. The goals of this research are to classify and understand the diversity of hydraulic architecture across major plant groups and growth forms by evaluating the extent of trade-offs of hydraulic against mechanical functions of xylem. This will be accomplished by determining how several key vascular network traits such as hydraulic conductivity, conduit number and area, and water transport velocity change from near the base of the plant to its uppermost branches. These results will be plotted on graphs to generate hydraulic landscapes. The positions of different plant types on these landscapes will indicate the extent to which the mechanical support function of xylem constrains its hydraulic function. Palms and vines are expected to be more hydraulically efficient than trees because, unlike trees, their xylem only transports water and does not provide structural support. Within temperate trees, a negative relationship between hydraulic efficiency and the proportion of wood devoted to xylem conduits relative to other cell types is expected. Finally, restrictions on xylem structure imposed by freezing should make temperate trees less hydraulically efficient than tropical trees. This research will enhance understanding of intrinsic constraints on the growth and productivity of forests and other natural and managed ecosystems. Broader impacts of this work include training and mentoring opportunities for a postdoctoral scientist, undergraduate and graduate students, was well as for Latin American students who will participate in the work to be carried out in Panama at the Smithsonian Tropical Research Institute.

植物需要获得CO2进行光合作用，导致叶片被动损失大量水蒸气，这些水蒸气必须不断被木质部取代，木质部是一种运输组织，由数千个从根到叶的死的中空管道组成。 水力结构决定了木质部向叶片供水的能力和效率，从而限制了植物获得碳和生长的速率。 在许多木本植物中，木质部导管具有水分运输和机械支持的双重功能，导致机械稳定性部分牺牲水力效率。 本研究的目标是通过评估木质部的水力功能与机械功能之间的权衡程度，对主要植物类群和生长形式的水力结构的多样性进行分类和理解。 这将通过确定几个关键的维管网络特征，如水力传导率，导管数量和面积，以及水运输速度从植物的底部附近到其最高分支的变化来实现。 这些结果将绘制在图表上，以生成水力景观。 不同植物类型在这些景观上的位置将指示木质部的机械支撑功能对其水力功能的限制程度。 棕榈树和葡萄藤预计比树木更有水力效率，因为与树木不同，它们的木质部只运输水分，不提供结构支撑。在温带树木，水力效率和比例的木材致力于木质部导管相对于其他细胞类型之间的负相关关系预计。最后，冻结对木质部结构的限制应该使温带树木的水力效率低于热带树木。 这项研究将增进对森林和其他自然生态系统和管理下的生态系统的生长和生产力的内在制约因素的了解。 这项工作的更广泛影响包括为博士后科学家、本科生和研究生以及将参加在巴拿马史密森热带研究所开展的工作的拉丁美洲学生提供培训和指导机会。