Identifying Robust Decarbonization Pathways for the Western U.S. Electric Power System Under Deep Climate Uncertainty

IF 7.3 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES Earths Future Pub Date : 2024-09-27 DOI:10.1029/2024EF004769
Srihari Sundar, Flavio Lehner, Nathalie Voisin, Michael T. Craig
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Abstract

Climate change threatens the resource adequacy of future power systems. Existing research and practice lack frameworks for identifying decarbonization pathways that are robust to climate-related uncertainty. We create such an analytical framework, then use it to assess the robustness of alternative pathways to achieving 60% emissions reductions from 2022 levels by 2040 for the Western U.S. power system. Our framework integrates power system planning and resource adequacy models with 100 climate realizations from a large climate ensemble. Climate realizations drive electricity demand; thermal plant availability; and wind, solar, and hydropower generation. Among five initial decarbonization pathways, all exhibit modest to significant resource adequacy failures under climate realizations in 2040, but certain pathways experience significantly less resource adequacy failures at little additional cost relative to other pathways. By identifying and planning for an extreme climate realization that drives the largest resource adequacy failures across our pathways, we produce a new decarbonization pathway that has no resource adequacy failures under any climate realizations. This new pathway is roughly 5% more expensive than other pathways due to greater capacity investment, and shifts investment from wind to solar and natural gas generators. Our analysis suggests modest increases in investment costs can add significant robustness against climate change in decarbonizing power systems. Our framework can help power system planners adapt to climate change by stress testing future plans to potential climate realizations, and offers a unique bridge between energy system and climate modeling.

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在深度气候不确定性下为美国西部电力系统确定稳健的去碳化途径
气候变化威胁着未来电力系统的资源充足性。现有的研究和实践缺乏确定去碳化路径的框架,而这些路径对与气候相关的不确定性具有稳健性。我们创建了这样一个分析框架,然后用它来评估美国西部电力系统到 2040 年实现比 2022 年减排 60% 的替代路径的稳健性。我们的框架将电力系统规划和资源充足性模型与来自大型气候集合的 100 种气候实景进行了整合。气候实景驱动电力需求、热电厂可用性以及风能、太阳能和水力发电。在五种最初的去碳化途径中,所有途径在 2040 年的气候变现条件下都表现出适度到严重的资源充足性失效,但某些途径的资源充足性失效情况要比其他途径少得多,而额外成本却很少。通过识别和规划一种极端气候变现,这种极端气候变现会导致所有路径中最大的资源充足性失效,因此我们提出了一种新的去碳化路径,这种路径在任何气候变现下都不会出现资源充足性失效。这条新路径的成本比其他路径高约 5%,原因是增加了产能投资,并将投资从风能转向太阳能和天然气发电机。我们的分析表明,投资成本的适度增加可以显著增强电力系统在去碳化过程中抵御气候变化的能力。我们的框架可以帮助电力系统规划者通过对未来计划进行压力测试以适应潜在的气候变现,从而适应气候变化,并在能源系统和气候建模之间架起了一座独特的桥梁。
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来源期刊
Earths Future
Earths Future ENVIRONMENTAL SCIENCESGEOSCIENCES, MULTIDI-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
11.00
自引率
7.30%
发文量
260
审稿时长
16 weeks
期刊介绍: Earth’s Future: A transdisciplinary open access journal, Earth’s Future focuses on the state of the Earth and the prediction of the planet’s future. By publishing peer-reviewed articles as well as editorials, essays, reviews, and commentaries, this journal will be the preeminent scholarly resource on the Anthropocene. It will also help assess the risks and opportunities associated with environmental changes and challenges.
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