Abstract
Liquid Air Energy Storage (LAES) is at pilot scale. Air cooling and liquefaction stores energy; reheating revaporises the air at pressure, powering a turbine or engine (Ameel et al., 2013). Liquefaction requires water & CO2 removal, preventing ice fouling. This paper proposes subsequent geological storage of this CO2 - offering a novel Carbon Dioxide Removal (CDR) by-product, for the energy storage industry. It additionally assesses the scale constraint and economic opportunity offered by implementing this CDR approach. Similarly, established Compressed Air Energy Storage (CAES) uses air compression and subsequent expansion. CAES could also add CO2scrubbing and subsequent storage, at extra cost. CAES stores fewer joules per kilogram of air than LAES - potentially scrubbing more CO2 per joule stored. Operational LAES/CAES technologies cannot offer full-scale CDR this century (Stocker et al., 2014), yet they could offer around 4% of projected CO2 disposals for LAES and < 25% for current-technology CAES. LAES CDR could reach trillion-dollar scale this century (20 billion USD/year, to first order). A larger, less certain commercial CDR opportunity exists for modified conventional CAES, due to additional equipment requirements. CDR may be commercially critical for LAES/CAES usage growth, and the necessary infrastructure may influence plant scaling and placement. A suggested design for low-pressure CAES theoretically offers global-scale CDR potential within a century (ignoring siting constraints) - but this must be costed against competing CDR and energy storage technologies.
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References
Ameel B, T’Joen C, de Kerpel K, de Jaeger P, Huisseune H, van Belleghem M, de Paepe M (2013). Thermodynamic analysis of energy storage with a liquid air Rankine cycle. Applied Thermal Engineering, 52(1): 130–140
Carr G (2012). Sunny uplands: Alternative energy will no longer be alternative. The Economist, 21
Ding Y, Tong L, Zhang P, Li Y, Radcliffe J, Wang L (2016). Liquid air energy storage. In: Letcher T M, ed. Storing Energy: With Special Reference to Renewable Energy Sources. Holland: Elsevier, 167–181
Dorminey B (2014). Underwater compressed air energy storage: Fantasy or reality? Renewable Energy World
EIA (2013). EIA projects world energy consumption will increase 56% by 2040. US Energy Information Administration (EIA). Available at: http://eia.gov/todayinenergy/detail.php?id=12251
Energy Storage Association (2018). Mechanical energy storage. Available at: http://energystorage.org/why-energy-storage/technologies/
Fajardy M, Mac Dowell N (2018). The energy return on investment of BECCS: Is BECCS a threat to energy security? Energy & Environmental Science, 11(6): 1581–1594
Fuss S, Lamb W F, Callaghan M W, Hilaire J, Creutzig F, Amann T, Beringer T, de Oliveira Garcia W, Hartmann J, Khanna T, Luderer G, Nemet G F, Rogelj J, Smith P, Vicente J L V, Wilcox J, del Mar Zamora Dominguez M, Minx J C (2018). Negative emissions—part 2: Costs, potentials and side effects. Environmental Research Letters, 13(6): 063002
Gerlach A, Breyer C, Fischer M, Werner C (2015). Forecast of long-term PV installations: A discussion of scenarios range from IEA to the solar economy. In: 31st European Photovoltaic Solar Energy Conference and Exhibition. Hamburg, 2973–2981
Gurwick N P, Moore L A, Kelly C, Elias P (2013). with a focus on its stability in situ and its promise as a climate mitigation strategy. PLoS One, 8(9): e75932
Hansen J, Sato M, Kharecha P, Beerling D, Berner R, Masson-Delmotte V, Pagani M, Raymo M, Royer D L, Zachos J C (2008). Target atmospheric CO2: Where should humanity aim? Open Atmospheric Science Journal, 2(1): 217–231
IEA (2017). World Energy Outlook 2017. International Energy Agency (IEA). Available at: http://iea.org/reports/
Jülch V (2016). Comparison of electricity storage options using levelized cost of storage (LCOS) method. Applied Energy, 183: 1594–1606
Kaiser F (2015). Steady state analysis of existing compressed air energy storage plants. In: Power and Energy Student Summit, Dortmund
Kantharaj B, Garvey S, Pimm A (2015). Thermodynamic analysis of a hybrid energy storage system based on compressed air and liquid air. Sustainable Energy Technologies and Assessments, 11: 159–164
Köhler P, Hartmann J, Wolf-Gladrow D A, (2010). Geoengineering potential of artificially enhanced silicate weathering of olivine. Proceedings of the National Academy of Sciences, 107(47): 20228–20233
Koplow J P (2010). A fundamentally new approach to air-cooled heat exchangers. Sandia Report, SAND2010-0258. Albuquerque, NM: Sandia National Laboratories
Kriegler E, Edenhofer O, Reuster L, Luderer G, Klein D (2013). Is atmospheric carbon dioxide removal a game changer for climate change mitigation? Climatic Change, 118(1): 45–57
Luo X, Wang J, Dooner M, Clarke J (2015). Overview of current development in electrical energy storage technologies and the application potential in power system operation. Applied Energy, 137: 511–536
Mathiesen B V, Lund H, Karlsson K (2011). 100% Renewable energy systems, climate mitigation and economic growth. Applied Energy, 88(2): 488–501
Morgan R, Nelmes S, Gibson E, Brett G (2015). An analysis of a large- scale liquid air energy storage system. Proceedings of the Institution of Civil Engineers-Energy, 168(2): 135–144
Muratori M, Calvin K, Wise M, Kyle P, Edmonds J (2016). Global economic consequences of deploying bioenergy with carbon capture and storage (BECCS). Environmental Research Letters, 11(9): 095004
She X H, Peng X D, Nie B J, Leng X S, Zhang X S, Weng L K, Tong L G, Zheng L F, Wang L, Ding Y L (2017). Enhancement of round trip efficiency of liquid air energy storage through effective utilization of heat of compression. Applied Energy, 206: 1632–1642
Spector J (2017). LightSail energy enters ‘hibernation’ as quest for game-changing energy storage runs out of cash. Greentech Media. Available at: http://greentechmedia.com/articles/read/
Stocker T F, Qin D, Plattner G K, Tignor M M B, Allen S K, Boschung J, Nauels A, Xia Y, Bex V, Midgley P M (2014). Climate change 2013—The physical science basis. Working Group I Contribution to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge: Cambridge University Press
Stolaroff J K, Keith D W, Lowry G V (2008). Carbon dioxide capture from atmospheric air using sodium hydroxide spray. Environmental Science & Technology, 42(8): 2728–2735
Strahan D (2013). Liquid Air in the energy and transport systems: Opportunities for industry and innovation in the UK. The Centre for Low Carbon Futures
Sun Y, Gao B, Yao Y, Fang J, Zhang M, Zhou Y M, Chen H, Yang L Y (2014). Effects of feedstock type, production method, and pyrolysis temperature on biochar and hydrochar properties. Chemical Engineering Journal, 240: 574–578
von Hippel T (2018). Thermal removal of carbon dioxide from the atmosphere: Energy requirements and scaling issues. Climatic Change, 148: 491–501
You S, Ok Y S, Chen S S, Tsang D C W, Kwon E E, Lee J, Wang C H (2017). A critical review on sustainable biochar system through gasification: Energy and environmental applications. Bioresource Technology, 246: 242–253
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Lockley, A., von Hippel, T. The carbon dioxide removal potential of Liquid Air Energy Storage: A high-level technical and economic appraisal. Front. Eng. Manag. 8, 456–464 (2021). https://doi.org/10.1007/s42524-020-0102-8
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DOI: https://doi.org/10.1007/s42524-020-0102-8