Wetlands in a changing world: processes, feedbacks and the climate benefits of wetlands

不断变化的世界中的湿地：湿地的过程、反馈和气候效益

• 批准号: RGPIN-2019-04199
• 负责人: Knox, Sara
• 金额: $ 2.19万
• 依托单位: University of British Columbia
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Individual
• 财政年份: 2021
• 资助国家: 加拿大
• 起止时间: 2021-01-01 至 2022-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=737476
• 关键词: Wetlands; changing; world; processes; feedbacks

Among the numerous ecosystem services provided by wetlands, from wildlife habitat to water quality improvement, climate regulation is identified as one of their most important benefits to society. Wetland ecosystems play an important role in the global carbon (C) cycle; they provide the ideal environment for C sequestration and long-term storage of atmospheric carbon dioxide (CO2), yet they are also the largest single source of atmospheric methane (CH4), a much more potent greenhouse gas (GHG) than CO2 in the short term. Climate change has the potential to increase GHG emissions from wetlands, however, the consequences of rising temperatures on wetland GHG dynamics and C cycling remains uncertain. Furthermore, preventing further wetland loss and restoring wetland ecosystems has been identified as important in limiting future emissions to help meet climate goals. While wetlands have the potential to both amplify and attenuate global warming, wetland responses to climate and land-use change are still poorly understood. This research program aims to address this knowledge gap by providing an improved mechanistic understanding of the response of wetland C and GHG dynamics to climate variability and management. Over the next five years, we will investigate land-atmosphere interactions across three distinct natural and managed wetland ecosystems to quantify and compare annual GHG and C budgets, identify key controls on trace gas fluxes, and improve predictions of wetland C fluxes. The four short-term objectives of this research program are addressed through linked research activities that combine field-based measurements, remote sensing, and modeling to provide novel insights into the controls and timing of wetland C and GHG fluxes across a range of spatial and temporal scales. The core of this research program will be new and ongoing eddy covariance measurements of ecosystem-scale CO2, CH4, water and energy fluxes at the three wetland sites. These sites include a natural and restored bog in the Burns Bog Ecological Conservancy Area, BC, and a tidal marsh in the Boundary Bay Wildlife Management Area, BC. By conducting year-round measurements of trace gas fluxes across the sites, we will quantify annual C and GHG budgets across these wetland ecosystems to assess and compare their net warming or cooling effect on climate. We will also investigate the dominant controls on wetland GHG exchange across hourly to interannual time scales, explore how drivers vary across wetland types and between natural and restored sites, and characterize within-site spatial variability in trace gas fluxes. We will also link remote-sensing indices to flux tower measurements to model and upscale C fluxes in restored and natural wetlands. This research is critical to better predicting current and future contributions of wetlands to climate change, which is highly relevant for policies aiming to limit the level of global temperature rise.

在湿地提供的众多生态系统服务中，从野生动物栖息地到水质改善，气候调节被认为是它们对社会最重要的好处之一。湿地生态系统在全球碳(C)循环中发挥着重要作用；它们为碳固存和大气二氧化碳（CO2）的长期储存提供了理想的环境，但它们也是大气甲烷（CH4）的最大单一来源，CH4是一种短期内比二氧化碳强得多的温室气体（GHG）。气候变化有可能增加湿地的温室气体排放，然而，温度上升对湿地温室气体动态和碳循环的影响仍不确定。此外，防止湿地进一步流失和恢复湿地生态系统已被确定为限制未来排放以帮助实现气候目标的重要因素。虽然湿地有可能放大和减弱全球变暖，但湿地对气候和土地利用变化的反应仍然知之甚少。本研究计划旨在通过提供对湿地C和温室气体动态对气候变率和管理的响应的改进的机制理解来解决这一知识差距。在未来五年内，我们将研究三种不同的自然和管理湿地生态系统的陆地-大气相互作用，量化和比较年度温室气体和碳预算，确定微量气体通量的关键控制因素，并改进湿地碳通量的预测。本研究计划的四个短期目标是通过结合实地测量、遥感和建模的相关研究活动来解决的，以提供关于湿地C和温室气体通量在一系列空间和时间尺度上的控制和时间的新见解。该研究项目的核心将是对三个湿地生态系统尺度的CO2、CH4、水和能量通量进行新的和持续的涡动相关测量。这些地点包括卑诗省伯恩斯沼泽生态保护区的一个自然修复沼泽，以及卑诗省边界湾野生动物管理区的一个潮汐沼泽。通过对这些地点的微量气体通量进行全年测量，我们将量化这些湿地生态系统的年度碳和温室气体预算，以评估和比较它们对气候的净变暖或冷却效应。我们还将在小时至年际时间尺度上研究湿地温室气体交换的主要控制因素，探索不同湿地类型以及自然和恢复场地之间的驱动因素如何变化，并表征微量气体通量在场地内的空间变异性。我们还将把遥感指数与通量塔测量联系起来，模拟和提高恢复湿地和自然湿地的碳通量。这项研究对于更好地预测湿地对气候变化的当前和未来贡献至关重要，这与旨在限制全球气温上升水平的政策高度相关。