高原(数学)
边距(机器学习)
自然(考古学)
地质学
总有机碳
碳纤维
地球科学
环境科学
自然地理学
碳循环
环境化学
生态学
古生物学
地理
生态系统
化学
复合数
机器学习
计算机科学
数学分析
生物
数学
复合材料
材料科学
作者
Yongdong Zhang,Wenshan Yang,Peng Lü,Huan Fu,Manjia Chen
出处
期刊:Catena
[Elsevier BV]
日期:2024-10-22
卷期号:247: 108490-108490
被引量:22
标识
DOI:10.1016/j.catena.2024.108490
摘要
• OC burial rate was reconstructed in two alpine lakes over the past 160 years. • The drivers of OC burial rate were identified by analyzing OM input from specific sources. • Atmospheric N deposition had a more profound influence on OC burial rate than climate warming. • Drivers shaped the OC burial rate by altering aquatic productivity . The rate of organic carbon (OC) burial in lakes depends considerably on natural and anthropogenic factors. Delineating how and to what extent potential drivers shape a lake’s OC burial rate is crucial for anticipating OC sequestration under future environmental change scenarios. Alpine lakes provide valuable opportunities for studying the influence of climate warming and atmospheric nitrogen (N) deposition on OC burial in lakes, owing to the lack of human activities in their catchments; however, this aspect has not been sufficiently documented. Here, the OC burial rate was reconstructed in two alpine lakes (Heihai and Jiren) from the southeastern margin of the Tibetan Plateau over the past ∼ 160 years, and the associated drivers were identified by resolving the temporal trends in organic matter (OM) input from specific sources to lake sediments via paleolimnological methods. The results demonstrated a consistently low OC burial rate (6.21–10.86 g m −2 yr −1 ) in Lake Heihai. The low hydrogen index (HI), moderate Paq, and high long-chain n -alkane flux revealed that submerged macrophytes and terrestrial plants are major contributors to the sequestrated OC. The notable decrease in the OC burial rate after 1980 was hypothesized to be caused by regional climate warming during this period because a greater export of terrestrial materials under such a climate can inhibit light penetration, diminishing submerged macrophyte productivity and OM input. In contrast, the synchronous input of higher amounts of terrestrial plant OM was largely degraded owing to the increased water temperature and the intensification of water column stratification. In Lake Jiren, a notably high OC burial rate (13.82–46.75g m −2 yr −1 ) was observed. The high HI, Paq, and short-chain n -alkane flux showed that phytoplankton and submerged macrophytes were the major contributors to the sequestrated OC. The two-phase increase in the OC burial rate in this lake, including a slow increase after 1947 and a rapid increase after 1983, might have resulted from strengthening aquatic primary productivity and OM input, driven by anthropogenic intensification of nutrient emissions, especially reactive N, from highly urbanized areas and the subsequent long-term atmospheric transport and deposition of these materials over the lake basin. A comparative analysis of the results between the two lakes suggested that atmospheric N deposition has a stronger influence on the OC burial than climate warming. These drivers affect the OC burial rate by altering aquatic productivity rather than the terrestrial OM input. This study provides a basic for predicting future OC burial scenarios in warmer climates with more intense anthropogenic N emissions.
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