Roles John, Yarnold Jennifer, Hussey Karen, Hankamer Ben
Institute for Molecular Bioscience, The University of Queensland, 306 Carmody Road, Brisbane, QLD, 4072, Australia.
Centre for Policy Futures, Faculty of Humanities and Social Sciences, The University of Queensland, Brisbane, QLD, 4072, Australia.
Biotechnol Biofuels. 2021 Jun 7;14(1):133. doi: 10.1186/s13068-021-01972-4.
Microalgae-based high-density fuels offer an efficient and environmental pathway towards decarbonization of the transport sector and could be produced as part of a globally distributed network without competing with food systems for arable land. Variations in climatic and economic conditions significantly impact the economic feasibility and productivity of such fuel systems, requiring harmonized technoeconomic assessments to identify important conditions required for commercial scale up.
Here, our previously validated Techno-economic and Lifecycle Analysis (TELCA) platform was extended to provide a direct performance comparison of microalgae diesel production at 12 international locations with variable climatic and economic settings. For each location, historical weather data, and jurisdiction-specific policy and economic inputs were used to simulate algal productivity, evaporation rates, harvest regime, CapEx and OpEx, interest and tax under location-specific operational parameters optimized for Minimum Diesel Selling Price (MDSP, US$ L). The economic feasibility, production capacity and CO emissions of a defined 500 ha algae-based diesel production facility is reported for each.
Under a for-profit business model, 10 of the 12 locations achieved a minimum diesel selling price (MDSP) under US$ 1.85 L / US$ 6.99 gal. At a fixed theoretical MDSP of US$ 2 L (US$ 7.57 gal) these locations could achieve a profitable Internal Rate of Return (IRR) of 9.5-22.1%. Under a public utility model (0% profit, 0% tax) eight locations delivered cost-competitive renewable diesel at an MDSP of < US$ 1.24 L (US$ 4.69 gal). The CO emissions of microalgae diesel were about one-third of fossil-based diesel.
The public utility approach could reduce the fuel price toward cost-competitiveness, providing a key step on the path to a profitable fully commercial renewable fuel industry by attracting the investment needed to advance technology and commercial biorefinery co-production options. Governments' adoption of such an approach could accelerate decarbonization, improve fuel security, and help support a local COVID-19 economic recovery. This study highlights the benefits and limitations of different factors at each location (e.g., climate, labour costs, policy, C-credits) in terms of the development of the technology-providing insights on how governments, investors and industry can drive the technology forward.
基于微藻的高密度燃料为交通运输部门的脱碳提供了一条高效且环保的途径,并且可以作为全球分布式网络的一部分进行生产,而无需与粮食系统争夺耕地。气候和经济条件的变化会显著影响此类燃料系统的经济可行性和生产力,因此需要进行统一的技术经济评估,以确定商业规模扩大所需的重要条件。
在此,我们先前经过验证的技术经济和生命周期分析(TELCA)平台得到扩展,以直接比较在12个具有不同气候和经济环境的国际地点生产微藻柴油的性能。对于每个地点,利用历史天气数据以及特定辖区的政策和经济投入,在针对最低柴油销售价格(MDSP,美元/升)进行优化的特定地点运营参数下,模拟藻类生产力、蒸发率、收获方式、资本支出和运营支出、利息和税收。报告了每个地点一个定义的500公顷基于藻类的柴油生产设施的经济可行性、生产能力和二氧化碳排放量。
在盈利商业模式下,12个地点中有10个实现了最低柴油销售价格低于1.85美元/升(6.99美元/加仑)。在固定的理论最低柴油销售价格为2美元/升(7.57美元/加仑)的情况下,这些地点可以实现9.5%-22.1%的盈利内部收益率。在公共事业模式(0%利润,0%税收)下,八个地点以低于1.24美元/升(4.69美元/加仑)的最低柴油销售价格提供了具有成本竞争力的可再生柴油。微藻柴油的二氧化碳排放量约为化石柴油的三分之一。
公共事业模式可以降低燃料价格,使其具有成本竞争力,通过吸引推进技术和商业生物炼制联产选项所需的投资,为盈利的完全商业化可再生燃料产业之路迈出关键一步。政府采用这种方法可以加速脱碳、提高燃料安全性,并有助于支持当地的新冠疫情经济复苏。本研究强调了每个地点不同因素(如气候、劳动力成本、政策、碳信用)在技术发展方面的益处和局限性,为政府、投资者和行业如何推动该技术发展提供了见解。
