Is the Arctic Methane budget changing?

北极甲烷预算是否发生变化？

• 批准号: NE/I014683/1
• 负责人: Euan Nisbet
• 金额: $ 45.19万
• 依托单位: Royal Holloway University of London
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2011
• 资助国家: 英国
• 起止时间: 2011 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=NE%2FI014683%2F1
• 关键词: Arctic; Methane; budget; changing

Methane (CH4) is the second (after CO2) most important greenhouse gas. Sources of CH4 to the atmosphere, both natural and human-driven, have been intensively studied and are now well established; however, their global and regional estimates still suffer from large uncertainties. The region above the Arctic Circle is very important from this perspective because of a unique combination of CH4 emission sources which are active now, e.g. wetlands and forest fires, and those which may become active in the future owing to regional climate change. Potentially important future sources include thawing permafrost soils and CH4-rich oceanic sediments (clathrates). Since the Arctic has been warming much faster compared to the rest of the world, this may trigger various changes in the active CH4 sources as well as those that represent large pools of carbon (permafrost soil) or gaseous CH4 (clathrates). The goal of the proposed project is thus to locate and quantify major sources of Arctic CH4 emissions to the atmosphere and contribute to understanding how these emissions may change with further regional climate warming. At present, the number of Arctic CH4 measurements is simply not sufficient to either make reliable estimates of regional CH4 sources or to understand recent trends in atmospheric CH4 concentrations. In addition to scarce measurements, most Arctic CH4 studies have been supported by campaign-based observations of the local processes responsible for CH4 emissions, mostly in summer when the region is most accessible. But owing to the episodic, and in some instances seasonal, nature of most CH4 source emissions paired against sporadic campaign-based sampling, it has not been possible to produce reliable emission estimates of different Arctic CH4 sources. To address this problem, we propose to establish year-round continuous measurements of CH4 concentration and isotopic composition in ambient air, and to synchronise campaign-based studies with the expected seasonality and location of the CH4 source emissions. Since CH4 emitted from different sources has distinct isotopic 'signatures', it is possible to attribute the observed emissions to the particular sources. This approach requires a retrospective analysis of the air mass trajectories to establish the origin of air with the observed isotopic signature. To be more specific, we propose to establish continuous CH4 measurements at Teriberka, Russia (69.2N, 35.1E; NW Russian Arctic coast), which will provide new insight into central Eurasian Arctic processes. In addition, we plan to carry out detailed isotopic studies of ambient air from several locations in the European and Russian Arctic. These will be compared with records of Arctic air reaching the UK at measurement stations at Barra (Scotland) and Weybourne (Norfolk). Combining our datasets with those from the small number of other Arctic stations of our international colleagues, we will determine whether ongoing changes in the Arctic regional climate are resulting in increased CH4 emissions. Specifically, we will use these concentration and isotopic data with the p-TOMCAT chemical transport and Met Office NAME models to locate Arctic CH4 sources and quantify any interannual changes in emissions. In addition to these main objectives, we plan to make regular measurements of atmospheric concentrations of other gases (CO2, CO, N2O, SF6, H2, O2/N2 and Ar/N2) from glass bottles collected at several Arctic locations. Such measurements will not require additional collections or costs as they will be made in parallel to the CH4 measurements, improving cost efficiency. Measurement of other gas species will help to assess the linked Arctic processes and source emissions of these gases, both on land and at sea, e.g. fire emissions (increased CO), ocean warming, expansion of oceanic 'dead zone' (due to decreased amounts of dissolved O2) and thawing permafrost soils and wetlands.

甲烷（CH 4）是第二大温室气体（仅次于CO2）。对自然和人为的大气CH 4来源进行了深入研究，现已确定;然而，其全球和区域估计数仍存在很大的不确定性。从这一角度看，北极圈以上区域非常重要，因为其独特的CH 4排放源组合，既有目前活跃的CH 4排放源，如湿地和森林火灾，也有由于区域气候变化而可能在未来变得活跃的CH 4排放源。未来潜在的重要来源包括融化的永久冻土和富含甲烷的海洋沉积物（包合物）。由于北极的变暖速度比世界其他地区快得多，这可能会引发活性甲烷源以及代表大型碳库（永久冻土）或气态甲烷（笼形物）的各种变化。因此，拟议项目的目标是确定和量化北极大气中甲烷排放的主要来源，并帮助了解这些排放如何随着区域气候进一步变暖而变化。目前，北极甲烷测量的数量根本不足以对区域甲烷源作出可靠的估计，也不足以了解大气甲烷浓度的最近趋势。除了稀少的测量数据外，大多数北极甲烷研究都得到了对造成甲烷排放的当地过程的基于气候的观测的支持，这些观测大多发生在该地区最容易进入的夏季。但是，由于大多数甲烷源排放的偶发性，在某些情况下是季节性的，加上零星的基于温室气体的取样，不可能对北极不同的甲烷源产生可靠的排放估计。为了解决这个问题，我们建议建立全年连续测量环境空气中的CH 4浓度和同位素组成，并同步的预期季节性和位置的CH 4源排放量的研究。由于不同来源排放的甲烷具有不同的同位素“特征”，因此有可能将观测到的排放归因于特定的来源。这种方法需要对气团轨迹进行回顾性分析，以确定具有观测到的同位素特征的空气的来源。更具体地说，我们建议建立连续的CH 4测量在泰里贝卡，俄罗斯（69.2 N，35.1 E;西北俄罗斯北极海岸），这将提供新的见解，欧亚大陆中部北极过程。此外，我们计划对欧洲和俄罗斯北极地区几个地点的环境空气进行详细的同位素研究。这些将与巴拉（苏格兰）和韦伯恩（诺福克）测量站到达英国的北极空气记录进行比较。将我们的数据集与我们的国际同事的少数其他北极站的数据集相结合，我们将确定北极区域气候的持续变化是否导致CH 4排放量增加。具体来说，我们将使用这些浓度和同位素数据与p-TOMCAT化学运输和气象局NAME模型定位北极CH 4源，并量化排放量的任何年际变化。除了这些主要目标外，我们还计划定期测量在北极几个地点收集的玻璃瓶中其他气体（CO2、CO、N2 O、SF6、H2、O2/N2和Ar/N2）的大气浓度。这种测量将不需要额外的收集或费用，因为它们将与CH 4测量同时进行，从而提高了成本效率。对其他气体种类的测量将有助于评估与之相关的北极过程和这些气体在陆地和海洋上的排放源，例如火灾排放（增加的CO）、海洋变暖、海洋“死区”的扩大（由于溶解的O2量减少）以及永久冻土和湿地的融化。

项目成果

Revised methane emissions from the East Siberian Arctic Shelf EGU2015-11621

东西伯利亚北极陆架修订后的甲烷排放量 EGU2015-11621

• 发表时间: 2015
• 作者: Berchet, A.

AMAP Assessment Report 2015: Methane as an Arctic climate forcer. Arctic Monitoring and Assessment Program (AMAP) Oslo (Arcic Council)

2015 年 AMAP 评估报告：甲烷作为北极气候的推动者。

• 发表时间: 2015
• 作者: Arora, V.

Atmospheric constraints on the methane emissions from the East Siberian Shelf

• DOI: 10.5194/acp-16-4147-2016
• 发表时间: 2016-01-01
• 期刊: ATMOSPHERIC CHEMISTRY AND PHYSICS
• 影响因子: 6.3
• 作者: Berchet, Antoine;Bousquet, Philippe;Hermansen, Ove
• 通讯作者: Hermansen, Ove

Airborne quantification of net methane and carbon dioxide fluxes from European Arctic wetlands in Summer 2019.

• DOI: 10.1098/rsta.2021.0192
• 发表时间: 2022-01-24
• 期刊: Philosophical transactions. Series A, Mathematical, physical, and engineering sciences
• 作者: Barker PA;Allen G;Pitt JR;Bauguitte SJ;Pasternak D;Cliff S;France JL;Fisher RE;Lee JD;Bower KN;Nisbet EG
• 通讯作者: Nisbet EG

What atmospheric measurements tell us about methane emissions in the East Siberian Arctic Shelf

大气测量告诉我们有关东西伯利亚北极大陆架甲烷排放的信息

• 发表时间: 2015
• 期刊: AGU Fall Meeting Abstracts
• 作者: Bousquet P.