美国航空业面临的二氧化碳挑战以及到2050年实现净零排放的途径

IF 11.5 1区 工程技术 Q1 ENGINEERING, AEROSPACE
Luke L. Jensen , Philippe A. Bonnefoy , James I. Hileman , Jay T. Fitzgerald
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引用次数: 1

摘要

本文调查了实现美国2021年航空气候行动计划中概述的到2050年美国商业航空部门温室气体净零排放目标的潜在途径和相关要求。航空交通量(RTK)预计在2019年至2050年间将以平均每年2.0%的速度增长,这表明需要逐步并最终将排放量与交通量增长完全脱钩,以实现美国航空业的目标。飞机技术进步、运营效率提高、可持续航空燃料和基于市场的措施(MBM)被认为是实现这一目标的减排措施。参数分析框架用于为每种减排措施制定低、中、高减排情景。如果飞机技术、运营和燃料被冻结在2019年的水平,预计到2050年,航空业将排放约4.3亿吨二氧化碳。老旧飞机的退役,被当前一代的替代品所取代,可能占2050年总减排目标的17%。进一步引入先进的飞机技术可能会为实现这一目标贡献11%的额外系统级减排。运营改进可能贡献≈2%,范围从1.5%到4%。2050年剩余70%的排放将酌情通过可持续燃料和MBM相结合的方式来解决。燃料的贡献水平将取决于持续增加产量以满足航空需求,以及当前和未来燃料原料和生产途径的生命周期减排系数(ERF)的提高,从当前石油基燃料的0%到生命周期零排放的可持续航空燃料的100%。要实现到2050年SAF的净零排放目标,需要从2022年到2030年SAF产量每年增加57%,此后每年增加13%,到2050年达到100%的减排系数。MBM可以在考虑了所有其他行业内改进机会和目标后,填补剩余生命周期排放量之间的差距。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
The carbon dioxide challenge facing U.S. aviation and paths to achieve net zero emissions by 2050

This paper investigates the potential pathways and associated requirements to meet a goal of net-zero greenhouse gas (GHG) emissions from the US commercial aviation sector by 2050 as outlined in the US 2021 Aviation Climate Action Plan. Aviation traffic (RTK) is projected to grow at an average of 2.0% per annum between 2019 and 2050, suggesting that a progressive and ultimately total decoupling of emissions from traffic growth will be required to meet the US aviation sector goal. Aircraft technology advancements, operational efficiency improvements, sustainable aviation fuels, and market-based measures (MBM) are considered as emissions reductions measures towards the goal. A parametric analysis framework is used to develop low, medium, and high emission reduction scenarios for each of these emissions reduction measures. If aircraft technology, operations, and fuels were frozen at 2019 levels, the aviation sector is projected to emit ≈430 million tonnes of CO2 (MtCO2) in 2050. Retirements of older aircraft, replaced by current-generation alternatives, may contribute 17% of the total 2050 emissions reduction goal. Further introduction of advanced aircraft technologies may contribute an additional system-level 11% emissions reductions towards the goal. Operational improvements may contribute ≈2% with a range from 1.5 to 4%. The remaining 70% of emissions in 2050 will be addressed through a combination of sustainable fuels and MBM, where appropriate. The level of contribution from fuels will be dependent on continued production ramp-up to meet aviation demand as well as improvements in lifecycle emissions reduction factor (ERF) for current and future fuel feedstock and production pathways, ranging from 0% for current petroleum-based fuels to 100% for sustainable aviation fuels with zero life-cycle emissions. Meeting a net-zero emissions goal by 2050 with SAF would require an increase in SAF production by 57% annually from 2022 to 2030 and 13% per year thereafter, reaching 100% emissions reductions factor by 2050. MBM may fill the gap between residual lifecycle emissions after accounting for all other in-sector improvement opportunities and the goal.

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来源期刊
Progress in Aerospace Sciences
Progress in Aerospace Sciences 工程技术-工程:宇航
CiteScore
20.20
自引率
3.10%
发文量
41
审稿时长
5 months
期刊介绍: "Progress in Aerospace Sciences" is a prestigious international review journal focusing on research in aerospace sciences and its applications in research organizations, industry, and universities. The journal aims to appeal to a wide range of readers and provide valuable information. The primary content of the journal consists of specially commissioned review articles. These articles serve to collate the latest advancements in the expansive field of aerospace sciences. Unlike other journals, there are no restrictions on the length of papers. Authors are encouraged to furnish specialist readers with a clear and concise summary of recent work, while also providing enough detail for general aerospace readers to stay updated on developments in fields beyond their own expertise.
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