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Nanotechnology-Based Lithium-Ion Battery Energy Storage Systems

Author

Listed:
  • George Adu Asamoah

    (Department of Chemical and Biomolecular Engineering, University of Tennessee, Knoxville, TN 37996, USA)

  • Maame Korsah

    (College of Arts and Sciences, University of Tennessee, Chattanooga, TN 37403, USA)

  • Parimala Gnana Soundari Arockiam Jeyasundar

    (RathnaVel Subramaniam College of Arts and Science, Coimbatore 641402, Tamil Nadu, India)

  • Meraj Ahmed

    (Department of Soil Science, School of Agriculture, Lovely Professional University, Phagwara 144411, Punjab, India)

  • Sie Yon Lau

    (Department of Chemical and Energy Engineering, Curtin University, CDT 250, Miri 98009, Sarawak, Malaysia
    Center of New and Sustainable Energy Research and Venture (CONSERV), Curtin University Malaysia, CDT 250, Miri 98009, Sarawak, Malaysia)

  • Michael K. Danquah

    (Department of Chemical and Biomolecular Engineering, University of Tennessee, Knoxville, TN 37996, USA)

Abstract

Conventional energy storage systems, such as pumped hydroelectric storage, lead–acid batteries, and compressed air energy storage (CAES), have been widely used for energy storage. However, these systems face significant limitations, including geographic constraints, high construction costs, low energy efficiency, and environmental challenges. Among these, lead–acid batteries, despite their widespread use, suffer from issues such as heavy weight, sensitivity to temperature fluctuations, low energy density, and limited depth of discharge. Lithium-ion batteries (LIBs) have emerged as a promising alternative, offering portability, fast charging, long cycle life, and higher energy density. However, LIBs still face challenges related to limited lifespan, safety concerns (such as overheating), and environmental impact due to resource extraction and emissions. This review explores the introduction of nanotechnology as a transformative approach to enhance efficiency and overcome the limitations of LIBs. We provide an in-depth overview of various nanotechnology-based solutions for LIBs, focusing on their impact on energy density, cycle life, safety, and environmental sustainability. Additionally, we discuss advanced thermal analysis techniques used to assess and improve the performance of nanotechnology-enhanced LIBs. Finally, we examine the role of nanoparticles in the environmental remediation of LIBs, offering insights into how they can mitigate the ecological footprint of battery disposal and recycling. This review aims to highlight the potential of nanotechnology to revolutionize energy storage systems and address the growing demand for efficient and sustainable energy solutions.

Suggested Citation

  • George Adu Asamoah & Maame Korsah & Parimala Gnana Soundari Arockiam Jeyasundar & Meraj Ahmed & Sie Yon Lau & Michael K. Danquah, 2024. "Nanotechnology-Based Lithium-Ion Battery Energy Storage Systems," Sustainability, MDPI, vol. 16(21), pages 1-46, October.
    • Handle: RePEc:gam:jsusta:v:16:y:2024:i:21:p:9231-:d:1505674
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    References listed on IDEAS

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    1. Chengcheng Fang & Bingyu Lu & Gorakh Pawar & Minghao Zhang & Diyi Cheng & Shuru Chen & Miguel Ceja & Jean-Marie Doux & Henry Musrock & Mei Cai & Boryann Liaw & Ying Shirley Meng, 2021. "Pressure-tailored lithium deposition and dissolution in lithium metal batteries," Nature Energy, Nature, vol. 6(10), pages 987-994, October.
    2. Shovon Goutam & Jean-Marc Timmermans & Noshin Omar & Peter Van den Bossche & Joeri Van Mierlo, 2015. "Comparative Study of Surface Temperature Behavior of Commercial Li-Ion Pouch Cells of Different Chemistries and Capacities by Infrared Thermography," Energies, MDPI, vol. 8(8), pages 1-18, August.
    3. Budt, Marcus & Wolf, Daniel & Span, Roland & Yan, Jinyue, 2016. "A review on compressed air energy storage: Basic principles, past milestones and recent developments," Applied Energy, Elsevier, vol. 170(C), pages 250-268.
    4. Mortazavi, Bohayra & Yang, Hongliu & Mohebbi, Farzad & Cuniberti, Gianaurelio & Rabczuk, Timon, 2017. "Graphene or h-BN paraffin composite structures for the thermal management of Li-ion batteries: A multiscale investigation," Applied Energy, Elsevier, vol. 202(C), pages 323-334.
    5. Ameen, Muhammad Tahir & Ma, Zhiwei & Smallbone, Andrew & Norman, Rose & Roskilly, Anthony Paul, 2023. "Demonstration system of pumped heat energy storage (PHES) and its round-trip efficiency," Applied Energy, Elsevier, vol. 333(C).
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