Carbon budget concept and its deviation through the pulse response lens

IF 7.9 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Earth System Dynamics Pub Date : 2024-04-18 DOI:10.5194/esd-15-387-2024
Vito Avakumović
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Abstract

Abstract. The carbon budget concept states that the global mean temperature (GMT) increase is roughly linearly dependent on cumulative emissions of CO2. The proportionality is measured as the transient climate response to cumulative emissions of carbon dioxide (TCRE). In this paper, the deviations of the carbon budget from the strict linear relationship implied by the TCRE are examined through the lens of a temperature response to an emission pulse (i.e., pulse response) and its relationship with a nonlinear TCRE. Hereby, two sources of deviation are distinguished: emission scenario and climate state dependence. The former stems from the scenario choice, i.e., the specific emission pathway for a given level of cumulative emissions and the latter from the change in TCRE with changing climatic conditions. Previous literature argues for scenario independence using a stylized set of emission scenarios, and offers a way to fit a nonlinear carbon budget equation. This paper shows how the pulse response, viewed as a Green's function, gives a unifying perspective on both scenario and state dependence. Moreover, it provides an optimization program that tests the scenario independence under the full range of emission pathways for a given set of constraints. In a setup chosen in this paper, the deviations stemming from emission pathway choices are less than 10 % of the overall temperature increase and gradually diminish. Moreover, using the pulse response as a Green's function, the scenario-dependent effects of a reduced-complexity climate model were replicated to a high degree, confirming that the behavior of scenario-dependent deviations can be explained and predicted by the shape of the pulse response. Additionally, it is shown that the pulse response changes with climatic conditions, through which the carbon budget state dependency is explained. Using a pulse response as an approximation for a state-dependent TCRE, an alternative method to derive a nonlinear carbon budget equation is provided. Finally, it is shown how different calibrations of a model can lead to different degrees of carbon budget nonlinearities. The analysis is done using FaIRv2.0.0, a simple climate emulator model that includes climate feedback modifying the carbon cycle, along with a one-box model used for comparison purposes. The Green's function approach can be used to diagnose both models' carbon budget scenario dependency, paving the way for future investigations and applications with other and more complex models.
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从脉冲响应角度看碳预算概念及其偏差
摘要碳预算概念指出,全球平均气温(GMT)的上升与二氧化碳的累积排放量大致呈线性关系。该比例关系以二氧化碳累积排放量的瞬态气候响应(TCRE)来衡量。本文通过温度对排放脉冲的响应(即脉冲响应)及其与非线性 TCRE 的关系,研究了碳预算与 TCRE 所隐含的严格线性关系的偏差。因此,可以区分出两种偏差来源:排放情景和气候状态依赖性。前者源于情景选择,即给定累积排放水平的具体排放路径,后者源于 TCRE 随气候条件变化而变化。以往的文献利用一组风格化的排放情景来论证情景的独立性,并提供了一种拟合非线性碳预算方程的方法。本文展示了脉冲响应如何通过格林函数来统一情景和状态依赖性。此外,本文还提供了一个优化程序,用于测试在给定约束条件下,所有排放路径下的情景独立性。在本文选择的设置中,排放路径选择产生的偏差小于总体温度升高的 10%,并且会逐渐减小。此外,利用脉冲响应作为格林函数,高度复制了复杂度降低的气候模式的情景依赖效应,证实了情景依赖偏差的行为可以通过脉冲响应的形状来解释和预测。此外,研究还表明,脉冲响应会随着气候条件的变化而变化,碳预算状态依赖性就是通过这种变化得到解释的。利用脉冲响应作为与状态相关的 TCRE 的近似值,提供了推导非线性碳预算方程的替代方法。最后,说明了模型的不同校准如何导致不同程度的碳预算非线性。分析使用了 FaIRv2.0.0,这是一个简单的气候模拟模型,包括改变碳循环的气候反馈,以及一个用于比较的单箱模型。格林函数方法可用于诊断这两个模型的碳预算情景依赖性,为今后使用其他更复杂的模型进行研究和应用铺平道路。
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来源期刊
Earth System Dynamics
Earth System Dynamics GEOSCIENCES, MULTIDISCIPLINARY-
CiteScore
13.20
自引率
5.50%
发文量
61
审稿时长
36 weeks
期刊介绍: Earth System Dynamics (ESD) is a not-for-profit international scientific journal committed to publishing and facilitating public discussion on interdisciplinary studies focusing on the Earth system and global change. The journal explores the intricate interactions among Earth's component systems, including the atmosphere, cryosphere, hydrosphere, oceans, pedosphere, lithosphere, and the influence of life and human activity. ESD welcomes contributions that delve into these interactions, their conceptualization, modeling, quantification, predictions of global change impacts, and their implications for Earth's habitability, humanity, and the future dynamics in the Anthropocene.
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