Comparative life cycle greenhouse gas emissions assessment of battery energy storage technologies for grid applications
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Yelin Deng | S. Karellas | Xiaoqu Han | Jun Yan | Yanxin Li | L. Nie | Xiaofan Huang | D. Kourkoumpas
[1] M. Pons,et al. Life cycle assessment (LCA) for flow batteries: A review of methodological decisions , 2022, Sustainable Energy Technologies and Assessments.
[2] Yuanqiang Zhou,et al. Investigating greenhouse gas emissions and environmental impacts from the production of lithium-ion batteries in China , 2022, Journal of Cleaner Production.
[3] C. Yuan,et al. Cradle-to-gate life cycle assessment of all-solid-state lithium-ion batteries for sustainable design and manufacturing , 2022, The International Journal of Life Cycle Assessment.
[4] A. Hicks,et al. Environmental hotspots and greenhouse gas reduction potential for different lithium-ion battery recovery strategies , 2022, Journal of Cleaner Production.
[5] Guangming Li,et al. Comparative life cycle assessment of LFP and NCM batteries including the secondary use and different recycling technologies. , 2022, The Science of the total environment.
[6] A. Shukla,et al. Life cycle assessment of soluble lead redox flow battery , 2022, Journal of Cleaner Production.
[7] Florian Degen,et al. Life cycle assessment of the energy consumption and GHG emissions of state-of-the-art automotive battery cell production , 2021, Journal of Cleaner Production.
[8] Y. Biçer,et al. Life cycle assessment of compressed air, vanadium redox flow battery, and molten salt systems for renewable energy storage , 2021, Energy Reports.
[9] H. Jouhara,et al. Comparative environmental life cycle assessment of conventional energy storage system and innovative thermal energy storage system , 2021, International Journal of Thermofluids.
[10] M. Iturrondobeitia,et al. Environmental Impacts of Aqueous Zinc Ion Batteries Based on Life Cycle Assessment , 2021, Advanced Sustainable Systems.
[11] J. Schoenung,et al. Environmental benefit-detriment thresholds for flow battery energy storage systems: A case study in California , 2021 .
[12] K. Muttaqi,et al. Impact assessment of battery energy storage systems towards achieving sustainable development goals , 2021 .
[13] Mustafizur Rahman,et al. The greenhouse gas emissions’ footprint and net energy ratio of utility-scale electro-chemical energy storage systems , 2021 .
[14] J. Dewulf,et al. Life cycle assessment of lithium-ion batteries and vanadium redox flow batteries-based renewable energy storage systems , 2021, Sustainable Energy Technologies and Assessments.
[15] C. Scown,et al. Life‐Cycle Assessment Considerations for Batteries and Battery Materials , 2021, Advanced Energy Materials.
[16] M. Raugei,et al. Life cycle assessment of lithium‐ion battery recycling using pyrometallurgical technologies , 2021, Journal of Industrial Ecology.
[17] Mustafizur Rahman,et al. Assessment of energy storage technologies: A review , 2020 .
[18] Shuoyao Wang,et al. A comparative life cycle assessment on lithium-ion battery: Case study on electric vehicle battery in China considering battery evolution , 2020, Waste management & research : the journal of the International Solid Wastes and Public Cleansing Association, ISWA.
[19] Oladele A. Ogunseitan,et al. Flow battery production: Materials selection and environmental impact , 2020, Journal of Cleaner Production.
[20] M. Carvalho,et al. Life Cycle Assessment of Electric Vehicle Batteries: An Overview of Recent Literature , 2020 .
[21] Fikile R. Brushett,et al. Assessing the levelized cost of vanadium redox flow batteries with capacity fade and rebalancing , 2020 .
[22] I. Staffell,et al. Comparative life cycle assessment of lithium-ion battery chemistries for residential storage , 2020, Journal of Energy Storage.
[23] Stephanie L. Shaw,et al. Research gaps in environmental life cycle assessments of lithium ion batteries for grid-scale stationary energy storage systems: End-of-life options and other issues , 2020, Sustainable Materials and Technologies.
[24] A. Martins,et al. Life cycle assessment of a vanadium flow battery , 2020, Energy Reports.
[25] Ming Liu,et al. Thermodynamic analysis and life cycle assessment of supercritical pulverized coal-fired power plant integrated with No.0 feedwater pre-heater under partial loads , 2019, Journal of Cleaner Production.
[26] Jarod C. Kelly,et al. Life Cycle Analysis of Lithium-Ion Batteries for Automotive Applications , 2019, Batteries.
[27] A. Levasseur,et al. How can an optimized life cycle assessment method help evaluate the use phase of energy storage systems? , 2019, Journal of Cleaner Production.
[28] Nasrudin Abd Rahim,et al. Sizing and applications of battery energy storage technologies in smart grid system: A review , 2019, Journal of Renewable and Sustainable Energy.
[29] S. Bringezu,et al. Comparing Electrical Energy Storage Technologies Regarding Their Material and Carbon Footprint , 2018, Energies.
[30] Panagiotis Grammelis,et al. A review of key environmental and energy performance indicators for the case of renewable energy systems when integrated with storage solutions , 2018, Applied Energy.
[31] M. Weil,et al. Life Cycle Assessment of a Vanadium Redox Flow Battery. , 2018, Environmental science & technology.
[32] Yashen Lin,et al. Use-Phase Drives Lithium-Ion Battery Life Cycle Environmental Impacts When Used for Frequency Regulation. , 2018, Environmental science & technology.
[33] M. Skyllas-Kazacos,et al. A review of electrolyte additives and impurities in vanadium redox flow batteries , 2018, Journal of Energy Chemistry.
[34] Wei Liu,et al. Environmental impact analysis and process optimization of batteries based on life cycle assessment , 2018 .
[35] Sam F. Y. Li,et al. Highly selective sulfonated poly(ether ether ketone)/titanium oxide composite membranes for vanadium redox flow batteries , 2017 .
[36] Manuel Baumann,et al. CO2 Footprint and Life‐Cycle Costs of Electrochemical Energy Storage for Stationary Grid Applications , 2017 .
[37] Yelin Deng,et al. Life cycle assessment of lithium sulfur battery for electric vehicles , 2017 .
[38] Manuel Baumann,et al. The environmental impact of Li-Ion batteries and the role of key parameters – A review , 2017 .
[39] M. Fowler,et al. Benchmarking and selection of Power-to-Gas utilizing electrolytic hydrogen as an energy storage alternative , 2016 .
[40] Thierry Coosemans,et al. Environmental performance of electricity storage systems for grid applications, a life cycle approach , 2015 .
[41] Thomas Vogt,et al. Comparative life cycle assessment of battery storage systems for stationary applications. , 2015, Environmental science & technology.
[42] J. Tarascon,et al. Towards greener and more sustainable batteries for electrical energy storage. , 2015, Nature chemistry.