IBES, University of Aberdeen, Aberdeen, UK.
New Phytol. 2009 Dec;184(4):944-9. doi: 10.1111/j.1469-8137.2009.03022.x. Epub 2009 Sep 14.
*This study investigates the influence of vegetation composition on carbon (C) sequestration in a moss-dominated ecosystem in the Arctic. *A (13)C labelling study in an arctic wet meadow was used to trace assimilate into C pools of differing recalcitrance within grasses and mosses and to determine the retention of C by these plant groups. *Moss retained 70% of assimilated (13)C over the month following labelling, which represented half the growing season. By contrast, the vascular plants, comprising mostly grasses, retained only 40%. The mechanism underlying this was that moss allocated 80% of the (13)C to recalcitrant C pools, a much higher proportion than in grasses (56%). *This method enabled elucidation of a plant trait that will influence decomposition and hence persistence of assimilated C in the ecosystem. We predict that moss-dominated vegetation will retain sequestered C more strongly than a grass-dominated community. Given the strong environmental drivers that are causing a shift from moss to grass dominance, this is likely to result in a reduction in future ecosystem C sink strength.
本研究调查了植被组成对北极地区以苔藓为主的生态系统中碳(C)固存的影响。通过在北极湿地进行的 13C 标记研究,追踪同化产物进入草和苔藓中不同抗降解性的 C 库,并确定这些植物群对 C 的保留。在标记后的一个月内,苔藓保留了 70%的同化 13C,占生长季节的一半。相比之下,主要由草组成的维管束植物仅保留了 40%。其原因是苔藓将 80%的 13C 分配到抗降解性 C 库中,这一比例远高于草(56%)。该方法阐明了一种植物特性,这将影响生态系统中同化 C 的分解和因此的持久性。我们预测,以苔藓为主的植被将比以草为主的群落更强烈地保留固存的 C。鉴于导致从苔藓到草占优势的强烈环境驱动因素,这可能导致未来生态系统碳汇强度的降低。
