How can solar geoengineering and mitigation be combined under climate targets?

Earth system dynamics : ESD Pub Date : 2021-12-08 DOI:10.5194/esd-12-1529-2021

M. M. Khabbazan, Marius Stankoweit, E. Roshan, H. Schmidt, H. Held

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引用次数: 3

Abstract

Abstract. So far, scientific analyses have mainly focused on the pros and cons of solar geoengineering or solar radiation management (SRM) as a climate policy option in mere isolation. Here, we put SRM into the context of mitigation by a strictly temperature-target-based approach. As the main innovation, we present a scheme that extends the applicability regime of temperature targets from mitigation-only to SRM-mitigation analyses. We explicitly account for one major category of side effects of SRM while minimizing economic costs for complying with the 2 ∘C temperature target. To do so, we suggest regional precipitation guardrails that are compatible with the 2 ∘C target. Our analysis shows that the value system enshrined in the 2 ∘C target leads to an elimination of most of the SRM from the policy scenario if a transgression of environmental targets is confined to 1/10 of the standard deviation of natural variability. Correspondingly, about half to nearly two-thirds of mitigation costs could be saved, depending on the relaxation of the precipitation criterion. In addition, assuming a climate sensitivity of 3 ∘C or more, in case of a delayed enough policy, a modest admixture of SRM to the policy portfolio might provide debatable trade-offs compared to a mitigation-only future. Also, in our analysis which abstains from a utilization of negative emissions technologies, for climate sensitivities higher than 4 ∘C, SRM will be an unavoidable policy tool to comply with the temperature targets. The economic numbers we present must be interpreted as upper bounds in the sense that cost-lowering effects by including negative emissions technologies are absent. However, with an additional climate policy option such as carbon dioxide removal present, the role of SRM would be even more limited. Hence, our results, pointing to a limited role of SRM in a situation of immediate implementation of a climate policy, are robust in that regard. This limitation would be enhanced if further side effects of SRM are taken into account in a target-based integrated assessment of SRM.

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如何在气候目标下将太阳能地球工程和缓解措施结合起来?

摘要到目前为止，科学分析主要集中在太阳能地球工程或太阳能辐射管理（SRM）作为一种单独的气候政策选择的利弊上。在这里，我们通过严格的基于温度目标的方法将SRM纳入缓解环境中。作为主要创新，我们提出了一种方案，将温度目标的适用范围从仅缓解扩展到SRM缓解分析。我们明确说明了SRM的一大类副作用，同时最大限度地降低了遵守2 ∘C温度目标。为此，我们建议区域降水护栏与2 ∘C目标。我们的分析表明 ∘如果违反环境目标被限制在自然变异性标准偏差的1/10以内，则C目标将导致从政策场景中消除大部分SRM。相应地，根据降水标准的放宽，可以节省大约一半到近三分之二的缓解成本。此外，假设气候敏感性为3 ∘C或更高，在政策延迟足够的情况下，与仅缓解的未来相比，将SRM适度纳入政策组合可能会提供有争议的权衡。此外，在我们的分析中，不使用负排放技术，因为气候敏感性高于4 ∘C、 SRM将是遵守温度目标的一个不可避免的政策工具。我们提出的经济数字必须被解释为上限，因为通过包括负排放技术来降低成本的效果是不存在的。然而，如果有额外的气候政策选择，如去除二氧化碳，SRM的作用将更加有限。因此，我们的研究结果表明，在立即实施气候政策的情况下，SRM的作用有限，在这方面是稳健的。如果在基于目标的SRM综合评估中考虑SRM的进一步副作用，这一限制将得到加强。

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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Earth system dynamics : ESD

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