Peng, L. et al. A basic look at electrocatalytic sulfur reduction reactions. Nat. Catal. three762–770 (2020).
Zhao, C. et al. High-energy and long-duration cycling lithium-sulfur pouch cells via macroporous catalytic cathodes with double-terminal binding sites. Nat. Nanotechnology. 16166–173(2020).
Zhao, CX et al. Semi-fixed molecule electrocatalyst for high-performance lithium-sulfur batteries. J. Am. chemistry. Soc. 14319865~19872(2021).
Zhou, G., Chen, H. & Cui, Y. Energy density formulation for practical lithium-sulfur battery design. Nat. energy 7312–319(2022).
Li, G., Chen, Z. & Lu, J. Commercial lithium-sulfur batteries. chemistry 43–7 (2018).
Manthiram, A., Fu, Y., Chung, SH, Zu, C. & Su, Y. S. Rechargeable lithium-sulfur batteries. chemistry. Father. 11411751-11787(2014).
Fang, R. et al. More reliable lithium-sulfur batteries: status, solutions and prospects. Advanced breeding. 291606823(2017).
Pang, Q., Liang, Nat. energy One16132(2016).
Tikekar, MD, Choudhury, S., Tu, ZY & Archer, L.A. Electrolyte and interface design principles for stable lithium metal batteries. Nat. energy One16114–116120 (2016).
Yang, X., Luo, J. & Sun, X. Towards high-performance solid-state Li-S batteries: from basic understanding to engineering design. chemistry. Soc. Father. 492140~2195(2020).
Yang, Y. et al. Electrocatalysis of lithium-sulfur batteries under diluted electrolyte conditions. Anju. chemistry. International ed. 5715549-15552(2018).
Song, Y. et al. Electrocatalytic rationalization of Li-S chemistry through mediator design: Progress and prospects. Advanced Energy Mator. 101901075(2019).
Hua, W. et al. Selective catalysis addresses polysulfide migration in lithium-sulfur batteries. Advanced breeding. 332101006(2021).
Dibden, J.W., Smith, J.W., Zhou, N., Garcia-Araez, N. & Owen, J.R. Using experimental phase diagrams to predict solid product composition and formation in lithium-sulfur batteries. chemistry. communicator 5212885–12888 (2016).
Shen, Z. et al. Cation-doped ZnS catalyst for polysulfide conversion in lithium-sulfur batteries. Nat. Catal. 5555–563 (2022).
Zhong, Y. R et al. Surface chemistry of cobalt phosphide-stabilized lithium-sulfur batteries. J.Am. chemistry. Soc. 1401455~1459 (2018).
Xue, W. et al. Intercalation conversion hybrid cathodes that together enable Li-S full-cell architectures with excellent gravimetric and volumetric energy densities. Nat. energy 4374–382 (2019).
Du, Z. et al. Cobalt on nitrogen-doped graphene as a single-atom catalyst for high-sulfur content lithium-sulfur batteries. J.Am. chemistry. Soc. 1413977-3985(2019).
Zhou, G. et al. Catalytic oxidation of Li2S on metal sulfide surfaces for Li-S batteries. Progress Natl Acad. know america 114840–845 (2017).
De Heer, J. Principles of Le Châtelier and Braun. J. Chem. education 34375(1957).
Zhang, L. et al. In situ optical spectroscopy characterization for optimal design of lithium-sulfur batteries. chemistry. Soc. Father. 485432-5453(2019).
Li, H. et al. Revealing the design principles of lean electrolyte lithium metal anodes through in situ spectroscopy. J. Am. chemistry. Soc. 1422012~2022(2020).
Li, H. et al. Reversible electrochemical oxidation of sulfur in ionic liquids for high-voltage Al-S batteries. Nat. Common. 125714(2021).
Liu, L. & Corma, A. Metal catalysts for heterogeneous catalysis: from single atoms to nanoclusters and nanoparticles. chemistry. Father. 1184981-5079(2018).
Zou, Q. & Lu, Y. C. Solvent-dependent lithium sulfur redox reaction: an Operando UV-vis spectroscopy study. J. Phys. chemistry. Lett. 71518-1525(2016).
Li, H. et al. Revealing catalyst-solvent interactions in lean electrolyte sulfur reduction electrocatalysts for Li-S batteries. Anju. chemistry. International ed. 61e202213863(2022).
He, Q., Freiberg, ATS, Patel, MUM, Qian, S. & Gasteiger, H. A. Operando Identification of liquid intermediates in lithium-sulfur batteries by transmission UV-vis spectroscopy. J. Electrochemistry. Soc. 167080508(2020).
Hwang, J. et al. Perovskites in catalysis and electrocatalysis. science 358751–756 (2017).
Singh, JP, Park, JY, Chae, KH, Ahn, D. & Lee, S. Li (Survey of soft X-ray absorption spectroscopy of Ni.0.8public0.1net0.1)o2 Cathode material. nanomaterials 10759(2020).
Massalski, TB & Okamoto, H. Binary alloy phase diagram2nd edition (ASM International, 1990).
Kurata, H. & Colliex, C. Electronic energy loss core-edge structure of manganese oxide. physics. B revision 482102-2108 (1993).
Lin, F. et al. Synchrotron X-ray analysis techniques for studying the electrochemistry of materials in rechargeable batteries. chemistry. Father. 11713123–13186 (2017).
Mechanisms and dynamics of Fan, FY, Carter, WC & Chiang, YM Li.2S precipitation in lithium-sulfur batteries. Advanced breeding. 275203-5209(2015).
Bhargav, A., He, J., Gupta, A. & Manthiram, A. Lithium-sulfur batteries: Achieving the milestones that matter. line 4285–291(2020).
Vivanco, JP and Rodriguez-Monroy, C. Graphene applications in energy: state of the art and impact. in 16th LACCEI International Multi-Conference in Engineering, Education and Technology (2018).