Department of Biology, San Diego State University, San Diego, CA, USA.
Glob Chang Biol. 2013 Sep;19(9):2853-66. doi: 10.1111/gcb.12247. Epub 2013 Jul 24.
Regional quantification of arctic CO2 and CH4 fluxes remains difficult due to high landscape heterogeneity coupled with a sparse measurement network. Most of the arctic coastal tundra near Barrow, Alaska is part of the thaw lake cycle, which includes current thaw lakes and a 5500-year chronosequence of vegetated thaw lake basins. However, spatial variability in carbon fluxes from these features remains grossly understudied. Here, we present an analysis of whole-ecosystem CO2 and CH4 fluxes from 20 thaw lake cycle features during the 2011 growing season. We found that the thaw lake cycle was largely responsible for spatial variation in CO2 flux, mostly due to its control on gross primary productivity (GPP). Current lakes were significant CO2 sources that varied little. Vegetated basins showed declining GPP and CO2 sink with age (R(2) = 67% and 57%, respectively). CH4 fluxes measured from a subset of 12 vegetated basins showed no relationship with age or CO2 flux components. Instead, higher CH4 fluxes were related to greater landscape wetness (R(2) = 57%) and thaw depth (additional R(2) = 28%). Spatial variation in CO2 and CH4 fluxes had good satellite remote sensing indicators, and we estimated the region to be a small CO2 sink of -4.9 ± 2.4 (SE) g C m(-2) between 11 June and 25 August, which was countered by a CH4 source of 2.1 ± 0.2 (SE) g C m(-2) . Results from our scaling exercise showed that developing or validating regional estimates based on single tower sites can result in significant bias, on average by a factor 4 for CO2 flux and 30% for CH4 flux. Although our results are specific to the Arctic Coastal Plain of Alaska, the degree of landscape-scale variability, large-scale controls on carbon exchange, and implications for regional estimation seen here likely have wide relevance to other arctic landscapes.
由于景观高度异质性以及稀疏的测量网络,北极地区的二氧化碳和甲烷通量的区域量化仍然具有挑战性。阿拉斯加巴罗附近的大部分北极沿海冻原都是融湖循环的一部分,其中包括当前的融湖和一个 5500 年历史的植被融湖盆地时间序列。然而,这些特征的碳通量的空间变异性仍然严重研究不足。在这里,我们分析了 2011 年生长季节来自 20 个融湖循环特征的整个生态系统的二氧化碳和甲烷通量。我们发现,融湖循环在很大程度上是造成 CO2 通量空间变化的原因,主要是因为它控制了总初级生产力(GPP)。当前的湖泊是重要的 CO2 源,变化不大。植被盆地随着年龄的增长,GPP 和 CO2 汇呈下降趋势(分别为 R(2) = 67%和 57%)。从 12 个植被盆地中测量的 CH4 通量与年龄或 CO2 通量组成部分没有关系。相反,较高的 CH4 通量与更大的景观湿度(R(2) = 57%)和融深(额外 R(2) = 28%)有关。CO2 和 CH4 通量的空间变化具有良好的卫星遥感指标,我们估计该地区在 6 月 11 日至 8 月 25 日期间是一个小的 CO2 汇,为-4.9 ± 2.4(SE)g C m(-2),而 CH4 源为 2.1 ± 0.2(SE)g C m(-2)。我们的缩放实验结果表明,基于单个塔站点开发或验证区域估计可能会导致显著的偏差,对于 CO2 通量的平均偏差为 4 倍,对于 CH4 通量的平均偏差为 30%。尽管我们的结果是针对阿拉斯加北极沿海平原的,但在这里看到的景观尺度变化程度、对碳交换的大规模控制以及对区域估计的影响可能对其他北极景观具有广泛的相关性。
