The role of the iron and steel sector in achieving net zero U.S. CO2 emissions by 2050

IF 5.8 Q2 ENERGY & FUELS
Siddarth Durga, Simone Speizer, Jae Edmonds
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Abstract

The U.S. steel sector is a hard-to-abate sector because of its heavy dependence on fossil fuels and its high capital requirements. In 2015, the sector was one of the major carbon emitters, contributing 10 % of the U.S. industrial CO2 emissions. The ability to decarbonize the U.S. iron and steel sector directly affects the ability of the U.S. to achieve economy-wide net zero CO2 by 2050. In this paper, we use the Global Change Analysis Model (GCAM) to analyze different U.S. steel sector decarbonization pathways under varying technology, policy, and demand futures. These pathways provide insights on how various low-carbon steelmaking technologies such as those using carbon capture and storage (CCS), hydrogen, or scrap could help reduce U.S. steel emissions by mid-century. In our primary decarbonization pathway, we find that nearly all of the conventional fossil-based steelmaking capacity is fully integrated with CCS by 2050. However, without CCS availability, almost all of the conventional fossil-based steelmaking is phased-out by 2050 and is replaced by hydrogen-based production. Scrap-based production continues to remain vital across both of these decarbonization pathways. Furthermore, we find that demand reduction could help reduce the required levels of CCS and hydrogen-based production in the decarbonization pathways. Implementation of advanced energy efficiency measures could help substantially reduce the sector's energy usage. Finally, we observe that addressing the embodied carbon transfer associated with steel imports will be crucial for fully decarbonizing the U.S. steel sector.

钢铁行业在 2050 年实现美国二氧化碳净零排放中的作用
由于严重依赖化石燃料且资本要求高,美国钢铁行业是一个难以消退的行业。2015 年,该行业是主要的碳排放者之一,占美国工业二氧化碳排放量的 10%。美国钢铁行业去碳化的能力直接影响到美国到 2050 年实现整个经济二氧化碳净零排放的能力。在本文中,我们利用全球变化分析模型(GCAM)分析了在不同技术、政策和需求前景下美国钢铁行业的不同脱碳途径。这些路径提供了各种低碳炼钢技术(如使用碳捕集与封存(CCS)、氢或废钢的技术)到本世纪中叶如何帮助减少美国钢铁排放的见解。在我们的主要去碳化路径中,我们发现到2050年,几乎所有的传统化石基炼钢能力都与CCS完全集成。然而,如果没有 CCS,到 2050 年,几乎所有的传统化石基炼钢都将被淘汰,取而代之的是氢基生产。在这两种去碳化途径中,废钢生产仍然至关重要。此外,我们还发现,减少需求有助于降低去碳化途径中所需的碳捕获与储存和氢基生产水平。实施先进的能效措施有助于大幅减少该行业的能源使用量。最后,我们注意到,解决与钢铁进口相关的内含碳转移问题对美国钢铁行业的全面脱碳至关重要。
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来源期刊
Energy and climate change
Energy and climate change Global and Planetary Change, Renewable Energy, Sustainability and the Environment, Management, Monitoring, Policy and Law
CiteScore
7.90
自引率
0.00%
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