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Collaborative Research: Measurement and Modeling of Aerodynamic Interactions between Tree-Sway Motion and Turbulence in and above a Forest Canopy

合作研究：森林树冠内部及上方树木摇摆运动与湍流之间的空气动力学相互作用的测量和建模

基本信息

批准号：
1117922
负责人：
April Hiscox
金额：
$ 6.92万
依托单位：
University South Carolina Research Foundation
依托单位国家：
美国
项目类别：
Standard Grant
财政年份：
2010
资助国家：
美国
起止时间：
2010-12-01 至 2014-01-31
项目状态：
已结题

来源：
https://www.nsf.gov/awardsearch/showAward?AWD_ID=1117922&HistoricalAwards=false
关键词：
Collaborative Research Measurement Modeling Aerodynamic

项目摘要

Turbulence in the canopy roughness sublayer (CRSL) is the primary driving force of the exchange processes between terrestrial ecosystems and the atmosphere. These exchanges are vital components in global carbon and water cycles and climate change research. Previous studies of short crops have shown that the aeroelasticity of plants has a significant impact on CRSL turbulence structure. The aeroelasticity of trees, however, has not been formally considered in most turbulence models of CRSL, including state of the art large-eddy simulation models (LES). This is largely due to a lack of field experiments to quantify the elastic properties of trees and their complex damped sway behaviors, which differ from those in short crops. Improved understanding and modeling of the aerodynamic interactions between forest canopies and CRSL turbulence are also significant in order to investigate the multifaceted effects of winds on the structure and function of terrestrial forest ecosystems and their responses to and interactions with future climate change. Intellectual merit: This collaborative project is an interdisciplinary effort built upon the experimental and numerical modeling expertise of forest ecologists and micrometeorologists at the University of Connecticut, East Carolina University and Louisiana State University. The research consists of a novel but labor intensive field experiment campaign over a period of 1.5 years at an established AmeriFlux forest site at Howland, Maine, and a computationally intensive modeling component to incorporate tree sway motion physics into a current LES. The investigators will develop improved numerical models of tree-sway and their coupling with the LES. The overall goal is to improve understanding and modeling of the mechanisms underlying the aerodynamic interactions between CRSL turbulence structures and tree sway motions in and above forest canopies. The field campaign will measure the sway motions and the elastic and aerodynamic properties of a large array of trees and turbulence wind fields simultaneously. These measurements will be used to quantify the temporal and spatial characteristics of tree-sway motions and their aerodynamic interactions with coherent gusts in a forest canopy. The coupled LES-tree-sway-model will be used to quantify the influences of tree sway motions on airflow in and above a forest over a range of atmospheric conditions. In addition, the PIs will conduct systematic investigations, using the coupled LES-tree-sway-model, to quantify the effects and the relative significances of atmospheric boundary layer height and stability, external horizontal pressure gradient force, canopy morphology and elastic properties of trees, on the characteristics of tree-sway motions and CRSL coherent structures and their interactions. The PIs will carry out a thorough and comprehensive set of analyses of field measurements and LES outputs to create both qualitative and quantitative descriptions of the spatial and temporal characteristics of the tree-sway motions and canopy-scale coherent structures, including their relations and interactions. Broader impacts: This collaborative project will integrate teaching and research at multiple levels of education. To cultivate and nurture the pursuit of science at the grass roots, the PIs will carry out an education program specifically designed to engage primary school children with interactive instructions on how basic data are collected, analyzed and shared, and demonstrations of the linkages between weather, climate and forested ecosystems. This outreach via family public education program will excite future generations about scientific understanding of the world, and will utilize some of the knowledge, instruments and models applied in the research portion of this project. This project will provide support to graduate students who will receive formal training in multiple research areas (micrometeorology, boundary-layer meteorology, forest meteorology, forest ecology), learn and practice important field measurement and numerical modeling and data analysis techniques. Research results from this project will be used to develop undergraduate and graduate course modules in micrometeorology, forest meteorology and forest ecology at both universities, and made available through a project web site.

冠层粗糙度亚层（CRSL）中的湍流是陆地生态系统与大气交换过程的主要驱动力。这些交换是全球碳和水循环以及气候变化研究的重要组成部分。以往对矮作物的研究表明，植物的气动弹性对CRSL湍流结构有显著影响。然而，在CRSL的大多数湍流模型中，包括最先进的大涡模拟模型（LES）中，树木的气动弹性尚未被正式考虑。这在很大程度上是由于缺乏实地实验来量化树木的弹性特性及其复杂的阻尼摇摆行为，这与短作物不同。森林冠层和CRSL湍流之间的空气动力学相互作用的更好的理解和建模也很重要，以调查风对陆地森林生态系统的结构和功能的多方面影响，以及它们对未来气候变化的响应和相互作用。智力优点：这个合作项目是一个跨学科的努力，建立在康涅狄格大学，东卡罗莱纳大学和路易斯安那州立大学的森林生态学家和微气象学家的实验和数值模拟专业知识。该研究包括一个新的，但劳动密集型的现场实验活动，在一个既定的AmeriFlux森林网站在豪兰，缅因州，在1.5年的时间，和计算密集型建模组件，将树摇摆运动物理到当前LES。研究人员将开发改进的树木摇摆的数值模型及其与LES的耦合。总体目标是提高对CRSL湍流结构和森林冠层内及上方树木摇摆运动之间的气动相互作用机制的理解和建模。现场活动将同时测量大量树木和湍流风场的摇摆运动以及弹性和空气动力学特性。这些测量将被用来量化的时间和空间特征的树木摇摆运动和它们的空气动力学相互作用与相干阵风在森林冠层。耦合LES树摇摆模式将被用来量化的影响，树木摇摆运动气流在森林和上方的一系列大气条件。此外，研究员将利用LES-树木摇摆耦合模式进行系统研究，以量化大气边界层高度和稳定性、外部水平压力梯度力、树冠形态和树木弹性特性对树木摇摆运动和CRSL相干结构及其相互作用特征的影响和相对重要性。PI将对现场测量结果和LES输出进行全面而全面的分析，以定性和定量地描述树木摇摆运动和树冠尺度相干结构的空间和时间特征，包括它们之间的关系和相互作用。更广泛的影响：这个合作项目将整合教学和研究在多个层次的教育。为了在基层培养和培养对科学的追求，PI将开展一项教育计划，专门针对小学生，就如何收集，分析和共享基本数据进行互动指导，并展示天气，气候和森林生态系统之间的联系。通过家庭公共教育计划的这种推广将激发后代对世界的科学理解，并将利用本项目研究部分应用的一些知识，工具和模型。该项目将为研究生提供支持，他们将在多个研究领域（微气象学，边界层气象学，森林气象学，森林生态学）接受正式培训，学习和实践重要的实地测量和数值建模以及数据分析技术。这一项目的研究成果将用于在两所大学编制微气象学、森林气象学和森林生态学的本科生和研究生课程单元，并通过一个项目网站提供。