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[90] P. Arora and Z. J. Zhang. Battery Separators. Chemical Reviews 104, 4419–4462 (2004). [91] X. Huang. Separator technologies for lithium-ion batteries. Journal of Solid State Electrochemistry 15, 649–662 (2011). [92] B. G. Morin and J. L. Schaeffer. Single-layer lithium ion battery separator (2012). U.S. patent app. 13/112,809. [93] M. Rao, X. Song, and E. J. Cairns. Nano-carbon/sulfur composite cathode materials with carbon nanofiber as electrical conductor for advanced secondary lithium/sulfur cells. Journal of Power Sources 205, 474–478 (2012). [94] M. Rao, W. Li, and E. J. Cairns. Porous carbon-sulfur composite cathode for lithium/sulfur cells. Electrochemistry Communications 17, 1–5 (2012). [95] J. Cannarella and C. B. Arnold. Ion transport restriction in mechanically strained separator membranes. Journal of Power Sources 226, 149–155 (2013). [96] H. Zhao, S.-J. Park, F. Shi, Y. Fu, V. Battaglia, P. N. Ross, and G. Liu. Propy- lene Carbonate (PC)-Based Electrolytes with High Coulombic Efficiency for Lithium-Ion Batteries. Journal of The Electrochemical Society 161, A194–A200 (2014). [97] J. T. Dudley, D. P. Wilkinson, G. Thomas, R. LeVae, S. Woo, H. Blom, C. Horvath, M. W. Juzkow, B. Denis, P. Juric, P. Aghakian, and J. R. Dahn. Conductivity of electrolytes for rechargeable lithium batteries. Journal of Power Sources 35, 59–82 (1991). [98] T. Yim, M.-S. Park, J.-S. Yu, K. J. Kim, K. Y. Im, J.-H. Kim, G. Jeong, Y. N. Jo, S.-G. Woo, K. S. Kang, I. Lee, and Y.-J. Kim. Effect of chemical reactivity of polysulfide toward carbonate-based electrolyte on the electrochemical performance of Li-S batteries. Electrochimica Acta 107, 454–460 (2013). [99] E. Peled, Y. Sternberg, A. Gorenshtein, and Y. Lavi. Lithium-Sulfur Battery: Eval- uation of Dioxolane-Based Electrolytes. Journal of The Electrochemical Society 136, 1621–1625 (1989). [100] D.-R. Chang, S.-H. Lee, S.-W. Kim, and H.-T. Kim. Binary electrolyte based on tetra(ethylene glycol) dimethyl ether and 1,3-dioxolane for lithium-sulfur battery. Jour- nal of Power Sources 112, 452–460 (2002). [101] J.-W. Choi, J.-K. Kim, G. Cheruvally, J.-H. Ahn, H.-J. Ahn, and K.-W. Kim. Rechargeable lithium/sulfur battery with suitable mixed liquid electrolytes. Elec- trochimica Acta 52, 2075–2082 (2007). 161PDF Image | Lithium-Sulfur Battery: Design, Characterization, and Physically-based Modeling
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