高变暖情景下赤道太平洋ENSO驱动的二氧化碳通量变化的对比预测

Pradeebane Vaittinada Ayar, L. Bopp, J. Christian, T. Ilyina, J. Krasting, R. Séférian, H. Tsujino, M. Watanabe, A. Yool, J. Tjiputra
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引用次数: 9

摘要

摘要厄尔尼诺Niño-Southern涛动(ENSO)广泛地调节着全球碳循环。更具体地说,它改变了热带海洋中碳的净吸收。事实上,在热带太平洋,海洋在厄尔尼诺Niño期间释放的碳较少,而在厄尔尼诺Niña期间则相反。本文评估了来自最新的耦合模式比对项目(CMIP6)的地球系统模式(esm)模拟观测到的热带太平洋CO2通量对ENSO响应变率的能力。不同模式间CO2通量异常的时间幅度和空间程度差异较大,而El Niño和La Niña相的地表温度信号一般表现较好。在高变暖共享社会经济路径(SSP5-8.5)情景之后的历史条件下,大约一半的esm模拟了ENSO-CO2通量关系的逆转。这种早在21世纪上半叶就出现的逐渐转变与CO2引起的Revelle因子的高升高有关,后者导致CO2分压(pCO2)对ENSO相间表面温度变化的敏感性增强。同时,人为CO2的吸收显著增加了上层海洋溶解无机碳(DIC)浓度(降低了其在温跃层中的垂直梯度),减弱了enso调制的表层DIC变化。ENSO-CO2通量关系对未来气候变化的响应对热带地区碳酸盐离子浓度的当代平均状态敏感。我们在模拟的当代碳酸盐浓度与预估的累积CO2通量之间提出了一个紧急约束。模拟ENSO-CO2通量关系变化的模式模拟了表面碳酸盐浓度的正偏置。
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Contrasting projections of the ENSO-driven CO2 flux variability in the equatorial Pacific under high-warming scenario
Abstract. The El Niño–Southern Oscillation (ENSO) widely modulates the global carbon cycle. More specifically, it alters the net uptake of carbon in the tropical ocean. Indeed, over the tropical Pacific less carbon is released by oceans during El Niño, while the opposite is the case for La Niña. Here, the skill of Earth system models (ESMs) from the latest Coupled Model Intercomparison Project (CMIP6) to simulate the observed tropical Pacific CO2 flux variability in response to ENSO is assessed. The temporal amplitude and spatial extent of CO2 flux anomalies vary considerably among models, while the surface temperature signals of El Niño and La Niña phases are generally well represented. Under historical conditions followed by the high-warming Shared Socio-economic Pathway (SSP5-8.5) scenarios, about half the ESMs simulate a reversal in ENSO–CO2 flux relationship. This gradual shift, which occurs as early as the first half of the 21st century, is associated with a high CO2-induced increase in the Revelle factor that leads to stronger sensitivity of partial pressure of CO2 (pCO2) to changes in surface temperature between ENSO phases. At the same time, uptake of anthropogenic CO2 substantially increases upper-ocean dissolved inorganic carbon (DIC) concentrations (reducing its vertical gradient in the thermocline) and weakens the ENSO-modulated surface DIC variability. The response of the ENSO–CO2 flux relationship to future climate change is sensitive to the contemporary mean state of the carbonate ion concentration in the tropics. We present an emergent constraint between the simulated contemporary carbonate concentration with the projected cumulated CO2 fluxes. Models that simulate shifts in the ENSO–CO2 flux relationship simulate positive bias in surface carbonate concentrations.
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