School of Geography Science, Nanjing Normal University, Nanjing 210023, PR China.
School of Geography Science, Nanjing Normal University, Nanjing 210023, PR China; Jiangsu Center for Collaborative Innovation in Geographical Information Resource Development and Application, Nanjing Normal University, Nanjing 210023, PR China; Key Laboratory of Virtual Geographic Environment (Nanjing Normal University), Ministry of Education, Nanjing 210023, PR China; State Key Laboratory Cultivation Base of Geographical Environment Evolution (Jiangsu Province), Nanjing 210023, PR China.
Sci Total Environ. 2020 Dec 1;746:140615. doi: 10.1016/j.scitotenv.2020.140615. Epub 2020 Jul 9.
Lakes are important organic carbon (OC) traps in the global carbon cycle. Recent studies have shown that the rate of OC burial in lacustrine sediments is influenced by factors such as climate change, land-use change, and eutrophication. In this study, we use multiproxy methods to reveal the mechanisms of lacustrine sediment OC burial in an alpine lake (Cuopu Lake), in southwest China. Combined with the dating from Pb and n-alkanes distribution analysis using the Positive Matrix Factorization model, the sedimentary history was divided into five stages: religious activity (the 1840s-1880s), earthquake (the 1880s-1910s), garrison (the 1910s-1960s), transition (the 1960s-1990s), and ecotourism (the 1990s-2010s). During the earthquake stage, OC burial was dominated by terrestrial solids (>40%) and co-precipitated algae (>30%), with a rapid deposition rate (>4 mm a) and low OC concentration (<4 mg g). During the other stages, when the level of disturbance was relatively low, a change in nutrient conditions either promoted or inhibited plant growth, which influenced the type of buried OC. The contribution of OC derived from combustion sources varied from stage to stage. Severe anthropogenic disturbances have led to a significant increase in nutritional levels in the lake water, leading to an increase in the OC burial rate. Climate change, which leads to changes in temperature and rainfall, did not significantly influence OC burial, whereas nitrogen deposition (and associated ecological changes) was a significant determinant. When the general mechanism is dominant, the total nitrogen to inorganic phosphorus ratio is an effective indicator of OC burial due to its selective promotion of different plant types. In conclusion, our results suggest that lacustrine sediment OC burial is closely linked to physical and anthropogenic factors in Cuopu Lake, as well as similar montane lakes.
湖泊是全球碳循环中重要的有机碳(OC)汇。最近的研究表明,湖泊沉积物中 OC 的埋藏速率受到气候变化、土地利用变化和富营养化等因素的影响。在本研究中,我们使用多指标方法揭示了中国西南高山湖泊(错普湖)中湖泊沉积物 OC 埋藏的机制。结合 Pb 定年和正矩阵因子分析模型的 n-烷烃分布分析,将沉积历史分为五个阶段:宗教活动(19 世纪 40 年代至 1880 年代)、地震(1880 年代至 1910 年代)、驻军(1910 年代至 1960 年代)、转型(1960 年代至 1990 年代)和生态旅游(1990 年代至 2010 年代)。在地震阶段,OC 的埋藏主要由陆地固体(>40%)和共沉淀藻类(>30%)主导,具有快速的沉积速率(>4mm a)和低 OC 浓度(<4mg g)。在其他阶段,当干扰水平相对较低时,营养条件的变化促进或抑制了植物的生长,从而影响了埋藏 OC 的类型。OC 来源的燃烧源的贡献因阶段而异。严重的人为干扰导致湖水营养水平显著升高,导致 OC 埋藏速率增加。气候变化导致温度和降雨量的变化,对 OC 埋藏没有显著影响,而氮沉降(和相关的生态变化)是一个重要的决定因素。当普遍机制占主导地位时,总氮与无机磷的比值是 OC 埋藏的有效指标,因为它对不同的植物类型具有选择性促进作用。总之,我们的结果表明,错普湖的湖泊沉积物 OC 埋藏与物理和人为因素密切相关,与类似的高山湖泊也密切相关。
