Multi-century dynamics of the climate and carbon cycle under both high and net negative emissions scenarios

C. Koven, V. Arora, P. Cadule, R. Fisher, C. Jones, D. Lawrence, J. Lewis, K. Lindsay, S. Mathesius, M. Meinshausen, M. Mills, Zebedee R. J. Nicholls, B. Sanderson, R. Séférian, N. Swart, W. Wieder, K. Zickfeld
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引用次数: 13

Abstract

Abstract. Future climate projections from Earth system models (ESMs) typically focus on the timescale of this century. We use a set of five ESMs and one Earth system model of intermediate complexity (EMIC) to explore the dynamics of the Earth's climate and carbon cycles under contrasting emissions trajectories beyond this century to the year 2300. The trajectories include a very-high-emissions, unmitigated fossil-fuel-driven scenario, as well as a mitigation scenario that diverges from the first scenario after 2040 and features an “overshoot”, followed by a decrease in atmospheric CO2 concentrations by means of large net negative CO2 emissions. In both scenarios and for all models considered here, the terrestrial system switches from being a net sink to either a neutral state or a net source of carbon, though for different reasons and centered in different geographic regions, depending on both the model and the scenario. The ocean carbon system remains a sink, albeit weakened by carbon cycle feedbacks, in all models under the high-emissions scenario and switches from sink to source in the overshoot scenario. The global mean temperature anomaly is generally proportional to cumulative carbon emissions, with a deviation from proportionality in the overshoot scenario that is governed by the zero emissions commitment. Additionally, 23rd century warming continues after the cessation of carbon emissions in several models in the high-emissions scenario and in one model in the overshoot scenario. While ocean carbon cycle responses qualitatively agree in both globally integrated and zonal mean dynamics in both scenarios, the land models qualitatively disagree in zonal mean dynamics, in the relative roles of vegetation and soil in driving C fluxes, in the response of the sink to CO2, and in the timing of the sink–source transition, particularly in the high-emissions scenario. The lack of agreement among land models on the mechanisms and geographic patterns of carbon cycle feedbacks, alongside the potential for lagged physical climate dynamics to cause warming long after CO2 concentrations have stabilized, points to the possibility of surprises in the climate system beyond the 21st century time horizon, even under relatively mitigated global warming scenarios, which should be taken into consideration when setting global climate policy.
高排放和净负排放情景下气候和碳循环的多世纪动态
摘要地球系统模式(esm)对未来气候的预测通常集中在本世纪的时间尺度上。我们使用一组5个esm和一个中等复杂程度的地球系统模型(EMIC)来探索地球气候和碳循环的动态,对比本世纪以后到2300年的排放轨迹。这些轨迹包括一种排放非常高、未经缓解的化石燃料驱动情景,以及一种缓解情景,该情景与2040年后的第一种情景不同,其特点是“超调”,随后通过大量负二氧化碳排放的方式使大气二氧化碳浓度下降。在这两种情景和这里考虑的所有模型中,陆地系统从净碳汇转变为中性状态或净碳源,尽管由于不同的原因并且集中在不同的地理区域,这取决于模型和情景。在高排放情景下的所有模型中,海洋碳系统仍然是一个汇,尽管受到碳循环反馈的削弱,在超调情景下,海洋碳系统从汇向源转换。全球平均温度异常通常与累积碳排放成正比,在由零排放承诺控制的超调情景中偏离比例。此外,在高排放情景下的几个模式和超调情景下的一个模式中,23世纪的变暖在碳排放停止后仍在继续。在这两种情景中,海洋碳循环响应在质量上与全球综合和地带性平均动力学一致,而陆地模式在地带性平均动力学、植被和土壤驱动碳通量的相对关系、汇对CO2的响应以及汇源转换的时间,特别是在高排放情景中,在质量上不一致。陆地模式对碳循环反馈的机制和地理格局缺乏一致性,以及滞后的气候物理动力学可能在二氧化碳浓度稳定后很长一段时间内导致变暖,这表明,即使在全球变暖相对缓解的情况下,21世纪以后气候系统也可能出现意外情况,在制定全球气候政策时应予以考虑。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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