The basal regions of continental ice sheets are gaps in our current understanding of the Earth's biosphere and biogeochemical cycles. We draw on existing and new chemical data sets for subglacial meltwaters to provide the first comprehensive assessment of sub-ice sheet biogeochemical weathering. We show that size of the ice mass is a critical control on the balance of chemical weathering processes and that microbial activity is ubiquitous in driving dissolution. Carbonate dissolution fueled by sulfide oxidation and microbial CO_2 dominate beneath small valley glaciers. Prolonged meltwater residence times and greater isolation characteristic of ice sheets lead to the development of anoxia and enhanced silicate dissolution due to calcite saturation. We show that sub-ice sheet environments are highly geochemically reactive and should be considered in regional and global solute budgets. For example, calculated solute fluxes from Antarctica (72-130 t yr~(-1)) are the same order of magnitude as those from some of the world's largest rivers and rates of chemical weathering (10-17 t km~(-2) yr~(-1)) are high for the annual specific discharge (2.3-4.1 × 10~(-3) m). Our model of chemical weathering dynamics provides important information on subglacial biodiversity and global biogeochemical cycles and may be used to design strategies for the first sampling of Antarctic Subglacial Lakes and other sub-ice sheet environments for the next decade.
展开▼
机译:在我们目前对地球生物圈和生物地球化学循环的了解中,大陆冰原的基础区域是空白。我们利用冰川下融水的现有和新化学数据集来提供对冰原生物地球化学风化的首次综合评估。我们表明,冰块的大小是化学风化过程平衡的关键控制,微生物活动在推动溶解中无处不在。硫化物氧化和微生物CO_2推动的碳酸盐溶解占主导地位的小山谷冰川之下。由于方解石饱和,延长的融水停留时间和更大的冰盖隔离特性会导致缺氧,并增加硅酸盐的溶解。我们表明,子冰盖环境具有高度的地球化学反应性,应在区域和全球溶质预算中予以考虑。例如,南极洲的溶质通量(72-130 t yr〜(-1))与世界上一些最大河流的溶质通量和化学风化率(10-17 t km〜(-2) )yr〜(-1))对于年比放电高(2.3-4.1×10〜(-3)m)。我们的化学风化动力学模型提供了有关冰下生物多样性和全球生物地球化学循环的重要信息,并可用于设计未来十年南极冰河湖泊和其他冰盖下环境的首次采样策略。
展开▼
