A geographic analysis and techno-economic assessment of renewable heat sources for low-temperature direct air capture in Europe

IF 9.9 1区 工程技术 Q1 ENERGY & FUELS Energy Conversion and Management Pub Date : 2024-11-11 DOI:10.1016/j.enconman.2024.119186
Luc F. Krull , Chad M. Baum , Benjamin K. Sovacool
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Abstract

Integrated assessment model (IAM) scenarios examining pathways to achieve the goals of the Paris Agreement stress the necessity of deploying carbon dioxide removal (CDR) methods, of which direct air capture (DAC) is viewed as one of the most promising. This study undertakes both a geospatial analysis and techno-economic assessment of potential heat sources for DAC to examine the economic impact of different renewable heat source systems on the capture costs of large-scale LT-DAC plants. It does this by determining the location of these plants through the paradigm of identifying the ideal geographic and economic environment for the selected heat sources. Thus, the research aims to answer the following research questions: What heat sources are optimally suited for low-temperature (LT) DAC and what conditions are feasible for setup? Which geographic locations represent the ideal environment within Europe for each heat source? How do the selected heat sources and geographic locations impact the economic viability of LT-DAC? Drawing on Climeworks’ LT-DAC approach as a focal case, the heat sources of geothermal energy, parabolic trough collector (PTC), industrial waste heat (IWH), and high-temperature heat pump (HTHP) were chosen, to be separately deployed in Iceland, Spain, Germany, and Norway, respectively. Spain emerged as a highly promising location for the PTC, IWH, and HTHP systems while Iceland is most suitable for the geothermal, IWH, and HTHP systems. Norway is a promising country mostly for deploying a HTHP system, whereas Germany faces primarily environmental and legal barriers. The techno-economic assessment identified great variation in the LCOD costs for the different heat source systems, with the geothermal energy system exhibiting the lowest costs at 175.63 €/tCO2 followed by the IWH, PTC, and HTHP systems. Future LCOD costs could potentially see a significant reduction of up to 66 % depending on the heat source system based on projected decreases in DAC CAPEX costs. A cost comparison revealed that current carbon price levels within the European Emission trading scheme are not expected to be sufficiently high enough to drive large investments in the development and scaling of LT-DAC. Cost levels of CCS technologies and LT-DAC could however be comparable, in particular for the geothermal energy system.
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欧洲低温直接空气捕获可再生热源的地理分析和技术经济评估
综合评估模型(IAM)方案对实现《巴黎协定》目标的途径进行了研究,强调了部署二氧化碳去除(CDR)方法的必要性,其中直接空气捕集(DAC)被视为最有前途的方法之一。本研究对 DAC 的潜在热源进行了地理空间分析和技术经济评估,以研究不同的可再生热源系统对大规模低温直接空气捕集(LT-DAC)工厂捕集成本的经济影响。为此,该研究通过确定所选热源的理想地理和经济环境范例来确定这些工厂的位置。因此,研究旨在回答以下研究问题:哪些热源最适合低温 (LT) DAC,哪些条件下可以安装?对于每种热源,哪些地理位置代表了欧洲的理想环境?所选热源和地理位置对低温空调系统的经济可行性有何影响?以 Climeworks 的 LT-DAC 方法为重点案例,选择了地热能、抛物线槽式集热器 (PTC)、工业余热 (IWH) 和高温热泵 (HTHP) 等热源,分别在冰岛、西班牙、德国和挪威进行部署。就 PTC、IWH 和 HTHP 系统而言,西班牙是极具潜力的地点,而冰岛则最适合地热、IWH 和 HTHP 系统。挪威是最有希望部署高温热电联产系统的国家,而德国则主要面临环境和法律障碍。技术经济评估发现,不同热源系统的 LCOD 成本差异很大,地热能源系统的成本最低,为 175.63 欧元/tCO2,其次是 IWH、PTC 和 HTHP 系统。根据 DAC CAPEX 成本的预计下降情况,未来的 LCOD 成本有可能大幅下降,根据热源系统的不同,降幅可达 66%。成本比较显示,目前欧洲排放交易计划中的碳价格水平预计不会高到足以推动对低温冷凝空调的开发和推广进行大量投资。然而,二氧化碳捕获与储存(CCS)技术和低温多联机空调系统(LT-DAC)的成本水平可以相媲美,尤其是地热能源系统。
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来源期刊
Energy Conversion and Management
Energy Conversion and Management 工程技术-力学
CiteScore
19.00
自引率
11.50%
发文量
1304
审稿时长
17 days
期刊介绍: The journal Energy Conversion and Management provides a forum for publishing original contributions and comprehensive technical review articles of interdisciplinary and original research on all important energy topics. The topics considered include energy generation, utilization, conversion, storage, transmission, conservation, management and sustainability. These topics typically involve various types of energy such as mechanical, thermal, nuclear, chemical, electromagnetic, magnetic and electric. These energy types cover all known energy resources, including renewable resources (e.g., solar, bio, hydro, wind, geothermal and ocean energy), fossil fuels and nuclear resources.
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