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Prototype systems for rechargeable magnesium batteries

Author

Listed:
  • D. Aurbach

    (Bar-Ilan University)

  • Z. Lu

    (Bar-Ilan University)

  • A. Schechter

    (Bar-Ilan University)

  • Y. Gofer

    (Bar-Ilan University)

  • H. Gizbar

    (Bar-Ilan University)

  • R. Turgeman

    (Bar-Ilan University)

  • Y. Cohen

    (Bar-Ilan University)

  • M. Moshkovich

    (Bar-Ilan University)

  • E. Levi

    (Bar-Ilan University)

Abstract

The thermodynamic properties of magnesium make it a natural choice for use as an anode material in rechargeable batteries, because it may provide a considerably higher energy density than the commonly used lead–acid and nickel–cadmium systems. Moreover, in contrast to lead and cadmium, magnesium is inexpensive, environmentally friendly and safe to handle. But the development of Mg batteries has been hindered by two problems. First, owing to the chemical activity of Mg, only solutions that neither donate nor accept protons are suitable as electrolytes; but most of these solutions allow the growth of passivating surface films, which inhibit any electrochemical reaction1,2,3. Second, the choice of cathode materials has been limited by the difficulty of intercalating Mg ions in many hosts4. Following previous studies of the electrochemistry of Mg electrodes in various non-aqueous solutions1,5, and of a variety of intercalation electrodes6,7, we have now developed rechargeable Mg battery systems that show promise for applications. The systems comprise electrolyte solutions based on Mg organohaloaluminate salts, and MgxMo3S4 cathodes, into which Mg ions can be intercalated reversibly, and with relatively fast kinetics. We expect that further improvements in the energy density will make these batteries a viable alternative to existing systems.

Suggested Citation

  • D. Aurbach & Z. Lu & A. Schechter & Y. Gofer & H. Gizbar & R. Turgeman & Y. Cohen & M. Moshkovich & E. Levi, 2000. "Prototype systems for rechargeable magnesium batteries," Nature, Nature, vol. 407(6805), pages 724-727, October.
    • Handle: RePEc:nat:nature:v:407:y:2000:i:6805:d:10.1038_35037553
    DOI: 10.1038/35037553
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    Cited by:

    1. Changhuan Zhang & Liran Zhang & Nianwu Li & Xiuqin Zhang, 2020. "Studies of FeSe 2 Cathode Materials for Mg–Li Hybrid Batteries," Energies, MDPI, vol. 13(17), pages 1-10, August.
    2. Krishnan, Syam G. & Arulraj, Arunachalam & Khalid, Mohammad & Reddy, M.V. & Jose, Rajan, 2021. "Energy storage in metal cobaltite electrodes: Opportunities & challenges in magnesium cobalt oxide," Renewable and Sustainable Energy Reviews, Elsevier, vol. 141(C).
    3. Navaratnarajah Kuganathan & Evangelos I. Gkanas & Alexander Chroneos, 2019. "Mg 6 MnO 8 as a Magnesium-Ion Battery Material: Defects, Dopants and Mg-Ion Transport," Energies, MDPI, vol. 12(17), pages 1-9, August.
    4. Yasumasa Tomita & Ryo Saito & Ayaka Nagata & Yohei Yamane & Yoshiumi Kohno, 2020. "Synthesis, Crystal Structure, and Ionic Conductivity of MgAl 2-x Ga x Cl 8 and MgGa 2 Cl 7 Br," Energies, MDPI, vol. 13(24), pages 1-9, December.
    5. Krzysztof Siczek, 2022. "Life-Related Hazards of Materials Applied to Mg–S Batteries," Energies, MDPI, vol. 15(4), pages 1-44, February.
    6. Menghao Yang & Yunsheng Liu & Yifei Mo, 2023. "Lithium crystallization at solid interfaces," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    7. Sergei Manzhos & Giacomo Giorgi, 2013. "Bridging the Fields of Solar Cell and Battery Research to Develop High-Performance Anodes for Photoelectrochemical Cells and Metal Ion Batteries," Challenges, MDPI, vol. 4(1), pages 1-20, June.
    8. Odoom-Wubah, Tareque & Rubio, Saúl & Tirado, José L. & Ortiz, Gregorio F. & Akoi, Bior James & Huang, Jiale & Li, Qingbiao, 2020. "Waste Pd/Fish-Collagen as anode for energy storage," Renewable and Sustainable Energy Reviews, Elsevier, vol. 131(C).

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