量化大气-陆地和海洋碳系统的记忆和持久性

M. Jonas, R. Bun, I. Ryzha, P. Żebrowski
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摘要

摘要在这里,我们打算从新的流变学(应力-应变)角度进一步了解化石燃料燃烧和土地使用造成的二氧化碳(CO2)排放量持续增加以及全球变暖所造成的地球负担(及其动态)。也就是说,我们将人为排放到大气中的二氧化碳视为一种压力源,并以应力-应变单位(应力单位为Pa,应变单位为1)调查地球的状况——允许访问和洞察以前未知的反映地球流变状态的特征。我们使用由弹性和阻尼(粘性)元素组成的麦克斯韦体的概念来反映大气-陆地和海洋系统对1850年至2015年间二氧化碳排放量持续增加的响应的整体行为。因此,从全球观察者的角度来看,我们看到大气中的二氧化碳浓度正在增加(相当快)。与此同时,大气正在变暖和膨胀,而一些碳被锁在陆地和海洋中(相当缓慢),同样受到全球变暖的影响。目前尚不清楚后一过程(碳汇吸收)相对于前一过程(大气膨胀)的可逆性和不同步程度。我们所知道的是,较慢的过程记住了较快的过程的影响,较快的过程在前面运行。重要的问题出现了,这种全球规模的记忆——地球的记忆——是否可以被识别和量化,它是如何动态地表现的,最后但并非最不重要的是,它是如何与我们理解地球路径依赖的持久性联系在一起的。我们超越了教科书知识,引入了表征系统的三个参数:延迟时间、内存和持久性。在其他条件相同的情况下,这三个参数仅取决于系统的特征粘弹性行为,从而可以对该系统进行更深入、更新颖的研究。这些参数有自己的限制,这些限制支配着大气-陆地和海洋碳系统的行为,独立于任何外部目标值(例如通过全球变化研究证明的温度目标)。我们发现,自1850年以来,大气-陆地和海洋系统在持久性方面逐渐被困住(即,系统将变得越来越难以放松),而其建立记忆的能力已经降低。一个系统有效地建立记忆的能力可以理解为它在其自然状态下的反应能力,或者,如果记忆的建立是有限的,作为将来全局系统故障的衡量标准。在1959年之前,大约60%的地球内存已经被人类利用。基于这些应力应变的见解,我们预计,如果目前的排放趋势不能立即和可持续地扭转,那么在2050年之前,大气-陆地和海洋碳系统将被迫脱离其自然状态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantifying memory and persistence in the atmosphere–land and ocean carbon system
Abstract. Here we intend to further the understanding of the planetary burden (and its dynamics) caused by the effect of the continued increase in carbon dioxide (CO2) emissions from fossil fuel burning and land use as well as by global warming from a new rheological (stress–strain) perspective. That is, we perceive the emission of anthropogenic CO2 into the atmosphere as a stressor and survey the condition of Earth in stress–strain units (stress in units of Pa, strain in units of 1) – allowing access to and insight into previously unknown characteristics reflecting Earth's rheological status. We use the idea of a Maxwell body consisting of elastic and damping (viscous) elements to reflect the overall behavior of the atmosphere–land and ocean system in response to the continued increase in CO2 emissions between 1850 and 2015. Thus, from the standpoint of a global observer, we see that the CO2 concentration in the atmosphere is increasing (rather quickly). Concomitantly, the atmosphere is warming and expanding, while some of the carbon is being locked away (rather slowly) in land and oceans, likewise under the influence of global warming. It is not known how reversible and how out of sync the latter process (uptake of carbon by sinks) is in relation to the former (expansion of the atmosphere). All we know is that the slower process remembers the influence of the faster one, which runs ahead. Important questions arise as to whether this global-scale memory – Earth's memory – can be identified and quantified, how it behaves dynamically, and, last but not least, how it interlinks with persistence by which we understand Earth's path dependency. We go beyond textbook knowledge by introducing three parameters that characterize the system: delay time, memory, and persistence. The three parameters depend, ceteris paribus, solely on the system's characteristic viscoelastic behavior and allow deeper and novel insights into that system. The parameters come with their own limits which govern the behavior of the atmosphere–land and ocean carbon system, independently from any external target values (such as temperature targets justified by means of global change research). We find that since 1850, the atmosphere–land and ocean system has been trapped progressively in terms of persistence (i.e., it will become progressively more difficult to relax the system), while its ability to build up memory has been reduced. The ability of a system to build up memory effectively can be understood as its ability to respond still within its natural regime or, if the build-up of memory is limited, as a measure for system failures globally in the future. Approximately 60 % of Earth's memory had already been exploited by humankind prior to 1959. Based on these stress–strain insights we expect that the atmosphere–land and ocean carbon system will be forced outside its natural regime well before 2050 if the current trend in emissions is not reversed immediately and sustainably.
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