Review and prospect on Metal-organic framework-based Separators for Lithium–Sulfur Battery

Authors

  • Bowen Liu

DOI:

https://doi.org/10.54097/qagp7b46

Keywords:

Lithium-sulfur batteries; MOFs; Separator.

Abstract

With the continuous advancement of technology, wearable smart devices and electric vehicles (EVs) have become an integral part of our daily lives. The increasing demand for energy from these devices and vehicles has driven the pursuit of high-performance rechargeable battery technology. In particular, the widespread adoption of electric vehicles has set higher standards for the energy density and cycle life of batteries. However, the energy density of the widely used lithium-ion batteries is currently limited by the theoretical capacity of commercial cathode materials, and there are certain challenges in terms of safety and cost-effectiveness. Therefore, the development of a new generation of rechargeable batteries with higher energy density, better safety, and more economical cost is particularly urgent. Lithium-sulfur batteries, due to their high energy density, high economic benefits, and high environmental friendliness, are considered to be one of the most promising successors to the widely used lithium-ion batteries. However, in practical applications, the electrochemical performance of lithium-sulfur batteries still needs to be improved. In particular, the poor conductivity of sulfur/lithium and the shuttle effect of polysulfides make the cycle life of the battery less than ideal, and lithium-sulfur batteries (LSB) are still far from achieving large-scale commercialization. The separator used in lithium-sulfur batteries plays a crucial role in its cycle performance and safety. The current commercial separator lacks the ability to effectively regulate the shuttle of polysulfides and is prone to thermal runaway at high temperatures. Therefore, to improve these issues, various functional materials have been used to modify the separator. Among them, as a new type of porous coordination polymer, metal organic frameworks (MOFs) have become a promising material for modifying separators due to their large specific surface area and highly ordered tunable nano-holes.At the same time, their rich inorganic nodes and designable organic ligands allow for the customization of pore chemistry at the molecular level, which can interact with the electroactive components in lithium-sulfur batteries in a tunable manner. This article reviews the reaction mechanism of lithium-sulfur batteries and the structural advantages of MOFs in terms of pore chemistry and morphology and briefly introduces the research progress of MOF-based interfacial layers for the functionalization of LSB separators in recent years. It elaborates on the mechanisms by which various modified separators improve electrochemical performance and provides a prospect for the development prospects of the field.

Downloads

Download data is not yet available.

References

[1] Blomgren, G. E. (2016). The development and future of lithium ion batteries. Journal of the Electrochemical Society, 164(1), A5019–A5025.

[2] T. Zhang, L. Zhang, L. Zhao, X. Huang, Y. Hou, Catalytic effects in the cathode of Li-S batteries: accelerating polysulfides redox conversion, Energy Chem (2020) 100036.

[3] Zheng, S., Khan, N., Worku, B. E., & Wang, B. (2024). Review and prospect on low-temperature lithium-sulfur battery. Chemical Engineering Journal, 484, 149610.

[4] Y. Zheng, S. Zheng, H. Xue, H. Pang, Metal-organic frameworks for lithium sulfur batteries, J. Mater. Chem. A 7 (2019) 3469–3491.

[5] G. Zhou, H. Chen, Y. Cui, Formulating energy density for designing practical lithium-sulfur batteries, Nat. Energy 7 (2022) 312–319

[6] Anion-Involved Solvation Structure of Lithium Polysulfides in Lithium–Sulfur Batteries

[7] G. Li, S. Wang, Y. Zhang, M. Li, Z. Chen, J. Lu, Revisiting the role of polysulfides in lithium-sulfur batteries, Adv. Mater. 30 (2018) 1705590

[8] Dong, Q.; Shen, R.; Li, C.; Gan, R.Y.; Ma, X.T.; Wang, J.C.; Li, J.; Wei, Z.D. Construction of Soft Base Tongs on Separator to Grasp Polysulfides from Shuttling in Lithium-Sulfur Batteries. Small 2018, 14, 1804277

[9] Song, C.W.; Peng, C.X.; Bian, Z.H.; Dong, F.; Xu, H.Y.; Zheng, S.Y. Stable and Fast Lithium–Sulfur Battery Achieved by Rational Design of Multifunctional Separator. Energy Environ. Mater. 2019, 2, 216–224

[10] Wang, P.; Xi, B.; Huang, M.; Chen, W.H.; Feng, J.K.; Xiong, S.L. Emerging catalysts to promote kinetics of lithium–sulfur batteries. Adv. Energy Mater. 2021, 11, 2002893

[11] Yaghi O M, Li H. Hydrothermal synthesis of a metal-organic framework containing large rectangular channels [J]. Journal of the American Chemical Society, 1995, 117(41): 10401-10402.

[12] Cohen S M. Postsynthetic methods for the functionalization of metal-organic Frameworks [J]. Chemical Reviews, 2012, 112(2): 970-1000.

[13] Furukawa H, Ko N, Go Y B, et al. Ultrahigh porosity in metal-organic frameworks [J]. Science, 2010, 329(5990): 424-428.

[14] Yang, H., Chang, Z., Qiao, Y., Deng, H., Mu, X., He, P., & Zhou, H. (2020). Constructing a super‐saturated electrolyte front surface for stable rechargeable aqueous zinc batteries. Angewandte Chemie International Edition, 59(24), 9377–9381.

[15] Zhao, C., Liu, J., Li, B., Ren, D., Chen, X., Yu, J., & Zhang, Q. (2020). Multiscale construction of bifunctional electrocatalysts for long‐lifespan rechargeable zinc–air batteries. Advanced Functional Materials, 30(36).

[16] Lai, G.-Q., Li, N., He, J., & LAN, Y.-Q. (2023). A ferrocene-modified stable metal–organic framework for efficient CO2 photoreduction reaction. Chemical Communications, 59(83), 12471–12474.

[17] Lv, Z., Xu, H., Xu, W., Peng, B., Zhao, C., Xie, M., Lv, X., GAO, Y., Hu, K., Fang, Y., Dong, W., & Huang, F. (2023). Quasi‐Topological intercalation mechanism of bi0.67nbs2 Enabling 100 C fast‐charging for sodium‐ion batteries. Advanced Energy Materials, 13(25).

[18] R. Razaq, M. M. U. Din, D. R. Småbråten, V. Eyupoglu, S. Janakiram,T. O. Sunde, N. Allahgoli, D. Rettenwander, L. Deng, Adv. Energy Mater. 2023, 13, 2302897.

[19] Kitao, T., Zhang, Y., Kitagawa, S., Wang, B., & Uemura, T. (2017). Hybridization of MOFs and polymers. Chemical Society Reviews, 46(11), 3108–3133.

[20] He, J., Chen, Y., & Manthiram, A. (2018). Vertical Co9S8 hollow nanowall arrays grown on a Celgard separator as a multifunctional polysulfide barrier for high-performance Li–S batteries. Energy & Environmental Science, 11(9), 2560–2568.

[21] Sumida, K., Rogow, D. L., Mason, J. A., McDonald, T. M., Bloch, E. D., Herm, Z. R., Bae, T.-H., & Long, J. R. (2011). Carbon dioxide capture in metal–organic frameworks. Chemical Reviews, 112(2), 724–781.

[22] He, Y., Chang, Z., Wu, S., Qiao, Y., Bai, S., Jiang, K., He, P., & Zhou, H. (2018). Simultaneously inhibiting lithium dendrites growth and polysulfides shuttle by a flexible mof‐based membrane in li–s batteries. Advanced Energy Materials, 8(34).

[23] Liu, D., Zhang, C., Zhou, G., Lv, W., Ling, G., Zhi, L., & Yang, Q. (2017). Catalytic effects in lithium–sulfur batteries: Promoted sulfur transformation and reduced shuttle effect. Advanced Science, 5(1).

[24] Qi, F., Sun, Z., Fan, X., Wang, Z., Shi, Y., Hu, G., & Li, F. (2021). Tunable interaction between metal‐organic frameworks and electroactive components in lithium–sulfur batteries: Status and perspectives. Advanced Energy Materials, 11(20).

[25] Yang, Y., Wang, Z., Jiang, T., Dong, C., Mao, Z., Lu, C., Sun, W., & Sun, K. (2018). A heterogenized Ni-doped zeolitic imidazolate framework to guide efficient trapping and catalytic conversion of polysulfides for greatly improved lithium–sulfur batteries. Journal of Materials Chemistry A, 6(28), 13593–13598.

[26] Steiger, J., Kramer, D., & Mönig, R. (2014). Microscopic observations of the formation, growth and shrinkage of lithium moss during electrodeposition and dissolution. Electrochimica Acta, 136, 529–536.

[27] Cao, R., Xu, W., Lv, D., Xiao, J., & Zhang, J. (2015b). Anodes for rechargeable lithium‐sulfur batteries. Advanced Energy Materials, 5(16).

[28] Xu, W., Wang, J., Ding, F., Chen, X., Nasybulin, E., Zhang, Y., & Zhang, J.-G. (2014). Lithium metal anodes for rechargeable batteries. Energy Environ. Sci., 7(2), 513–537.

[29] Bai, S., Sun, Y., Yi, J., He, Y., Qiao, Y., & Zhou, H. (2018b). High-Power li-metal anode enabled by metal-organic framework modified electrolyte. Joule, 2(10), 2117–2132.

Downloads

Published

07-11-2024

How to Cite

Liu, B. (2024). Review and prospect on Metal-organic framework-based Separators for Lithium–Sulfur Battery. Highlights in Science, Engineering and Technology, 116, 37-43. https://doi.org/10.54097/qagp7b46