更强的北极效应是由二氧化碳浓度的减少而不是增加造成的

Shi Zhou, Yu‐Chiao Liang, I. Mitevski, L. Polvani
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摘要

北极放大(AA)指的是北极变暖比全球其他地区变暖放大的现象,通常归因于大气中二氧化碳(CO2)浓度的增加。然而,很少有人注意到,当北极地区比地球其他地区大得多的地方变冷时,二氧化碳水平下降时AA的机制和数量变化。通过对大范围CO2浓度(相对于工业化前水平,从1/8×到8×CO2)强迫的气候模式试验的分析,我们发现,在CO2浓度降低的情况下,AA确实发生,并且比CO2浓度增加的情况下AA更强。反馈分析表明,Planck反馈、失效速率反馈和反照率反馈是CO2增减胁迫AA产生的主要因素,但随着CO2浓度的降低,失效速率反馈越强,AA越强。我们进一步发现,CO2浓度的增加将AA的高峰月份从11月推迟到12月或1月,这取决于强迫强度。相比之下,CO2水平的降低不能在10月之前改变AA的峰值,因为海冰的最大增加是在9月,与强迫强度无关。这种季节性变化也出现在衰减率反馈中,但不出现在其他反馈中,也不出现在大气和海洋热输运过程中。我们的研究结果强调了AA对CO2浓度增减的强烈不对称响应,表现为其强度和季节性的不同变化。这些发现对于理解碳去除如何影响北极气候、生态系统和社会经济活动具有重要意义。
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Stronger Arctic amplification produced by decreasing, not increasing, CO2 concentrations
Arctic amplification (AA), referring to the phenomenon of amplified warming in the Arctic compared to the warming in the rest of the globe, is generally attributed to the increasing concentrations of carbon dioxide (CO2) in the atmosphere. However, little attention has been paid to the mechanisms and quantitative variations of AA under decreasing levels of CO2, when cooling where the Arctic region is considerably larger than over the rest of the planet. Analyzing climate model experiments forced with a wide range of CO2 concentrations (from 1/8× to 8×CO2, with respect to preindustrial levels), we show that AA indeed occurs under decreasing CO2 concentrations, and it is stronger than AA under increasing CO2 concentrations. Feedback analysis reveals that the Planck, lapse-rate, and albedo feedbacks are the main contributors to producing AAs forced by CO2 increase and decrease, but the stronger lapse-rate feedback associated with decreasing CO2 level gives rise to stronger AA. We further find that the increasing CO2 concentrations delay the peak month of AA from November to December or January, depending on the forcing strength. In contrast, decreasing CO2 levels cannot shift the peak of AA earlier than October, as a consequence of the maximum sea-ice increase in September which is independent of forcing strength. Such seasonality changes are also presented in the lapse-rate feedback, but do not appear in other feedbacks nor in the atmospheric and oceanic heat transport processeses. Our results highlight the strongly asymmetric responses of AA, as evidenced by the different changes in its intensity and seasonality, to the increasing and decreasing CO2 concentrations. These findings have significant implications for understanding how carbon removal could impact the Arctic climate, ecosystems, and socio-economic activities.
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