从藻类到 HEFA:经济学与在美国的潜在应用

IF 3.2 4区 生物学 Q2 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Biofuels Bioproducts & Biorefining-Biofpr Pub Date : 2024-04-26 DOI:10.1002/bbb.2623
Swaroop Atnoorkar, Matthew Wiatrowski, Emily Newes, Ryan Davis, Steve Peterson
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引用次数: 0

摘要

要实现美国能源部 "可持续航空燃料(SAF)大挑战 "设定的目标,目前可用的原料可能还不够。因此,在进行投资和选址之前,必须优先考虑藻类原料的开发、原型设计和成本降低。随着藻类原料生产的发展,使用更成熟技术的简化转化方法有助于降低藻基燃料的投资风险。将工艺复杂性降低到本文所述的步骤[即,将脂类转化为 HEFA(加氢处理酯和脂肪酸)燃料,并将生物质的其余部分用于厌氧消化或食品/饲料生产],可在短期内生产出藻类 SAF,但根据可实现的培养成本和成分质量,其经济性具有挑战性。不过,这些经济性可以通过当前的政策激励措施得到改善。在这些激励措施的作用下,根据与石油相比所能实现的碳强度降低,模拟的藻类制氢烯烃途径的最低燃料销售价格可低至每汽油加仑当量 4.7 美元。藻类原料生产成熟度在当前和未来技术水平上的不确定性将在决定建设藻类制氢烯烃设施的经济可行性方面发挥重要作用。例如,如果不成熟的原料价格哪怕增加 10%,2050 年的 SAF 产量也只有成熟原料产量的 58%。此外,这种转化途径的增长可以通过纳入补贴,以及通过更高的副产品价值或更高的脂质产量来显著促进,这些都超出了本文所考虑的工艺范围。
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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Algae to HEFA: Economics and potential deployment in the United States

To reach the goals set by the US Department of Energy's Sustainable Aviation Fuel (SAF) Grand Challenge, currently available feedstocks may be insufficient. Giving priority to developing, prototyping and reducing the cost of algal feedstock before investing and lining up locations is important. As the production of algal feedstocks advances, a simplified conversion approach using more mature technologies can help reduce the investment risk for algae-based fuels. Reducing process complexity to the steps described here [namely, conversion of lipids to HEFA (hydroprocessed esters and fatty acids) fuels and relegating the remainder of the biomass to anaerobic digestion or food/feed production] enables the near-term production of algal SAF but presents challenging economics depending on achievable cultivation costs and compositional quality. However, these economics can be improved by present-day policy incentives. With these incentives, the modeled algae-to-HEFA pathway could reach a minimum fuel selling price as low as $4.7 per gasoline gallon equivalent depending on the carbon intensity reduction that can be achieved compared with petroleum. Uncertainty about algal feedstock production maturity in the current state of technology and the future will play a large role in determining the economic feasibility of building algae-to-HEFA facilities. For example, if immaturity increases the feedstock price by even 10%, SAF production in 2050 is about 58% of the production which could have been achieved with mature feedstock. Additionally, growth in this conversion pathway can be notably boosted through the inclusion of subsidies, and also through higher-value coproducts or higher lipid yields beyond the scope of the process considered here.

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来源期刊
CiteScore
7.80
自引率
5.10%
发文量
122
审稿时长
4.5 months
期刊介绍: Biofuels, Bioproducts and Biorefining is a vital source of information on sustainable products, fuels and energy. Examining the spectrum of international scientific research and industrial development along the entire supply chain, The journal publishes a balanced mixture of peer-reviewed critical reviews, commentary, business news highlights, policy updates and patent intelligence. Biofuels, Bioproducts and Biorefining is dedicated to fostering growth in the biorenewables sector and serving its growing interdisciplinary community by providing a unique, systems-based insight into technologies in these fields as well as their industrial development.
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