北部高纬度地区二氧化碳的季节振幅

Zhihua Liu, Brendan M. Rogers, Gretchen Keppel-Aleks, Manuel Helbig, Ashley P. Ballantyne, John S. Kimball, Abhishek Chatterjee, Adrianna Foster, Aleya Kaushik, Anna-Maria Virkkala, Arden L. Burrell, Christopher Schwalm, Colm Sweeney, Edward A. G. Schuur, Jacqueline Dean, Jennifer D. Watts, Jinhyuk E. Kim, Jonathan A. Wang, Lei Hu, Lisa Welp, Logan T. Berner, Marguerite Mauritz, Michelle Mack, Nicholas C. Parazoo, Nima Madani, Ralph Keeling, Roisin Commane, Scott Goetz, Shilong Piao, Susan M. Natali, Wenjuan Wang, Wolfgang Buermann, Xanthe Walker, Xin Lin, Xuhui Wang, Yuming Jin, Kailiang Yu, Yangjian Zhang
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摘要

全球气候变化正在影响大气中二氧化碳的季节周期振幅(SCA),其中北部高纬度地区(NHL; >45°N)的增幅最大。在本综述中,我们将以北极和北方陆地生态系统为重点,探讨影响北半球高纬度地区 SCA 的变化和内在机制。SCA的纬度梯度主要受温度和初级生产的季节性及其对生态系统碳动态的影响所支配。自 20 世纪 60 年代以来,NHL 的 SCA 增加了 50%,这主要是由于 NHL 陆地生态系统二氧化碳(CO2)净交换的季节性增强。温度对这一趋势的影响最大,这是因为气候变暖影响了生长季节的长度和植物的生产力;二氧化碳的施肥效应则起次要作用。欧亚寒带生态系统对 SCA 的影响最大,春季和夏季是影响最大的季节。在非生长季节,生态系统呼吸作用增强,显示出 SCA 对全球和地貌驱动因素响应的最大不确定性。预计观测到的季节振幅变化仍将持续。重点工作包括扩大碳通量和生态系统观测网络,特别是在苔原生态系统中,并将植被覆盖和永久冻土等驱动因素纳入过程模型,以更好地模拟北极圈内净二氧化碳交换的季节动态。大气二氧化碳季节循环振幅(SCA)的变化反映了全球碳循环的大规模变化。本综述总结了信号最强的北部高纬度地区正的 SCA 趋势,并探讨了驱动该趋势的潜在机制及其相对重要性。
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Seasonal CO2 amplitude in northern high latitudes
Global climate change is influencing the seasonal cycle amplitude of atmospheric CO2 (SCA), with the strongest increases at northern high latitudes (NHL; >45° N). In this Review, we explore the changes and underlying mechanisms influencing the NHL SCA, focusing on Arctic and boreal terrestrial ecosystems. Latitudinal gradients in the SCA are largely governed by seasonality in temperature and primary production, and their influence on ecosystem carbon dynamics. In the NHL, the SCA has increased by 50% since the 1960s, mostly due to enhanced seasonality in net carbon dioxide (CO2) exchange in NHL terrestrial ecosystems. Temperature most strongly influences this trend, owing to warming impacts on growing season length and plant productivity; CO2 fertilization effects have a secondary role. Eurasian boreal ecosystems exert the strongest influence on the SCA, and spring and summer are the most influential seasons. Enhanced ecosystem respiration during the non-growing season exhibits most uncertainty in the SCA response to global and landscape drivers. Observed changes in the seasonal amplitude are projected to continue. Key priorities include extending carbon flux and ecosystem observation networks, particularly in tundra ecosystems, and including drivers such as vegetation cover and permafrost in process models to better simulate seasonal dynamics of net CO2 exchange in the NHL. Changes in the seasonal cycle amplitude of atmospheric CO2 (SCA) reflect large-scale changes in the global carbon cycle. This Review summarizes the positive SCA trend in the northern high latitudes, where the signal is strongest, and explores the underlying mechanisms driving the trend and their relative importance.
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