Carbon dioxide fluxes on canadian arctic tundra

加拿大北极苔原上的二氧化碳通量

• 批准号: 331356-2012
• 负责人: Lafleur, Peter
• 金额: $ 1.46万
• 依托单位: Trent University
• 依托单位国家: 加拿大
• 项目类别: Discovery Grants Program - Northern Research Supplement
• 财政年份: 2015
• 资助国家: 加拿大
• 起止时间: 2015-01-01 至 2016-12-31
• 项目状态: 已结题
• 来源: https://www.nserc-crsng.gc.ca/ase-oro/Details-Detailles_eng.asp?id=572172
• 关键词: Carbon; dioxide; fluxes; canadian; arctic

The Arctic is experiencing unprecedented change due to global warming. Ecosystem processes, such as the exchange of carbon dioxide between tundra and atmosphere, are impacted by this warming. Our ability to predict future climate rests on understanding these changes. For the past eight years I have been building a research program with my students and collaborators to investigate Arctic tundra-atmosphere carbon dioxide exchange near Daring Lake, NWT, where carbon dioxide flux stations are set up in four different tundra environments. It is now the longest running and most extensive carbon flux measurement program in Arctic Canada. I am proposing to expand this research to address new crucial scientific issues that will improve out understanding of Arctic tundra processes and thus, generate knowledge that will assist in predictions of future climatic change. I will investigate how variations in plant growth, expressed as leaf area, control seasonal and interannual variations in carbon dioxide fluxes and compare these with climate factors such as temperature and precipitation. It is hypothesized that the plant factors are only indirectly related to climate factors and are more important than climate for determining the total amount of atmospheric carbon dioxide absorbed by the tundra. I will also explore novel ways for monitoring these vegetation changes, and ultimately carbon dioxide fluxes, which can be extrapolated to large geographic areas. I will extend the measurements into the late-winter and autumn seasons when we believe that the loss of carbon dioxide from the tundra is significant. In the past, due to technological limitations, measurements were primarily restricted to the snow-free growing season, but this can now be overcome with updated equipment and will give us the information needed to construct accurate annual carbon budgets for tundra ecosystems. This research will advance our knowledge of tundra processes and climate feedbacks, address the lack of carbon flux research in the Canadian Arctic, train new students in Arctic environmental science and ultimately, benefit northerners by improving climate predictions that will help communities plan for and adapt to climate change.

由于全球变暖，北极正在经历前所未有的变化。生态系统过程，如冻土带和大气之间的二氧化碳交换，受到这种变暖的影响。我们预测未来气候的能力取决于对这些变化的理解。在过去的八年里，我一直在与我的学生和合作者建立一个研究计划，调查北极苔原大气二氧化碳交换附近的Daring湖，NWT，在那里的二氧化碳通量站建立在四个不同的苔原环境。它现在是加拿大北极地区运行时间最长、范围最广的碳通量测量计划。我建议扩大这项研究，以解决新的关键科学问题，这将提高我们对北极苔原过程的理解，从而产生有助于预测未来气候变化的知识。我将研究植物生长的变化，表示为叶面积，控制二氧化碳通量的季节性和年际变化，并将其与温度和降水等气候因素进行比较。据推测，植物因素只是间接相关的气候因素，更重要的是比气候决定大气中的二氧化碳被冻土带吸收的总量。我还将探索监测这些植被变化的新方法，并最终监测二氧化碳通量，这可以外推到大的地理区域。我将把测量范围扩大到冬末和秋季，那时我们相信冻土带的二氧化碳损失是显著的。在过去，由于技术限制，测量主要限于无雪的生长季节，但现在可以通过更新的设备来克服这一点，并为我们提供构建冻土带生态系统准确年度碳预算所需的信息。这项研究将推进我们对苔原过程和气候反馈的了解，解决加拿大北极地区缺乏碳通量研究的问题，培训北极环境科学的新学生，最终通过改善气候预测使北方人受益，这将有助于社区规划和适应气候变化。