Assessing the feasibility of CO2 removal strategies in achieving climate-neutral power systems: Insights from biomass, CO2 capture, and direct air capture in Europe

IF 13 Q1 ENERGY & FUELS Advances in Applied Energy Pub Date : 2024-02-21 DOI:10.1016/j.adapen.2024.100166
Rebeka Béres , Martin Junginger , Machteld van den Broek
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Abstract

To achieve the European Union's goal of climate neutrality by 2050, negative emissions may be required to compensate for emissions exceeding allocated carbon budgets. Therefore, carbon removal technologies such as bioenergy with carbon capture (BECCS) and direct air capture (DAC) may need to play a pivotal role in the power system. To design carbon removal strategies, more insights are needed into the impact of sustainable biomass availability and the feasibility of carbon capture and storage (CCS), including the expensive and energy-intensive DAC on achieving net-zero and net-negative targets. Therefore, in this study the European power system in 2050 is modelled at an hourly resolution in the cost-minimization PLEXOS modelling platform. Three climate-neutral scenarios with targets of 0, -1, and -3.9 Mt CO2/year (which agree with varying levels of climate justice) are assessed for different biomass levels, and CCS availability. Findings under baseline assumptions reveal that in a climate-neutral power system with biomass and CCS options, it is cost-effective to complement variable renewable energy with a mix of combined cycle natural gas turbines (CCNGT) for flexibility and BECCS as base load to compensate for the CO2 emissions from natural gas and additional carbon removal in the net-negative scenarios. The role of these technologies becomes more prominent, with -3.9 GtCO2/year target. Limited biomass availability necessitates additional 0.4–4 GtCO2/year DAC, 10–50 GW CCNGT with CCS, and 10–50 GW nuclear. Excluding biomass doubles system costs and increases reliance on nuclear energy up to 300 TWh/year. The absence of CCS increases costs by 78%, emphasizing significant investments in bioenergy, nuclear power, hydrogen storage, and biogas. Sensitivity analysis and limitations of the study are fully discussed.

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评估二氧化碳去除战略在实现气候中和电力系统中的可行性:欧洲生物质、二氧化碳捕获和直接空气捕获的启示
为了实现欧盟到 2050 年气候中和的目标,可能需要负排放来补偿超出分配碳预算的排放量。因此,碳捕集生物能源(BECCS)和直接空气捕集(DAC)等碳清除技术可能需要在电力系统中发挥关键作用。为了设计碳清除战略,需要更深入地了解可持续生物质可用性的影响以及碳捕集与封存(CCS)的可行性,包括昂贵且能源密集的 DAC 对实现净零和净负目标的影响。因此,本研究在成本最小化 PLEXOS 建模平台上对 2050 年的欧洲电力系统进行了小时分辨率建模。针对不同的生物量水平和 CCS 可用性,评估了三种气候中和情景,其目标分别为 0、-1 和-390 万吨 CO2/年(符合不同程度的气候正义)。基线假设下的研究结果表明,在具有生物质和 CCS 选项的气候中和电力系统中,使用联合循环天然气涡轮机 (CCNGT) 作为可变可再生能源的补充以提高灵活性,并使用 BECCS 作为基本负荷以补偿天然气的二氧化碳排放和净负情景下的额外碳清除,是具有成本效益的。这些技术的作用变得更加突出,目标为-3.9 GtCO2/年。由于生物质供应有限,需要额外的 0.4-4 GtCO2/year DAC、10-50 GW CCNGT(含 CCS)和 10-50 GW 核能。如果不包括生物质能,系统成本将增加一倍,对核能的依赖将增加到每年 300 太瓦时。如果不使用 CCS,成本将增加 78%,这就需要对生物能源、核能、氢储存和沼气进行大量投资。研究的敏感性分析和局限性也得到了充分讨论。
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来源期刊
Advances in Applied Energy
Advances in Applied Energy Energy-General Energy
CiteScore
23.90
自引率
0.00%
发文量
36
审稿时长
21 days
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