High sulfur loading and shuttle inhibition of advanced sulfur cathode enabled by graphene network skin and N, P, F-doped mesoporous carbon interfaces for ultra-stable lithium sulfur battery
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C. Villevieille. Direct observation of lithium polysulfides in lithium-sulfur batteries using X-ray diffraction. 2017, 2: 17069.
Z. Q. Lin. Advancing performance and unfolding mechanism of lithium and sodium storage in SnO via precision synthesis of monodisperse PEG-ligated nanoparticles. 2022, 12: 2201015.
X. Q. Liu. SnO as advanced anode of alkali-ion batteries: Inhibiting Sn coarsening by crafting robust physical barriers, void boundaries, and heterophase interfaces for superior electrochemical reaction reversibility. 2020, 10: 1902657.
Y. G. Li. Towards practical lean-electrolyte Li-S batteries: Highly solvating electrolytes or sparingly solvating electrolytes?. 2022, 1: e9120012.
Y. Cui. Formulating energy density for designing practical lithium-sulfur batteries. 2022, 7: 312-319.
H. X. Ji. Cobalt in nitrogen-doped graphene as single-atom catalyst for high-sulfur content lithium-sulfur batteries. 2019, 141: 3977-3985.
Z. Lin. Foldable interpenetrated metal-organic frameworks/carbon nanotubes thin film for lithium-sulfur batteries. 2017, 8: 14628.
C. M. Chen. Semi-immobilized molecular electrocatalysts for high-performance lithium-sulfur batteries. 2021, 143: 19865-19872.
M. J. Park. Synthesis of three-dimensionally interconnected sulfur-rich polymers for cathode materials of high-rate lithium-sulfur batteries. 2015, 6: 7278.
Z. W. Chen. Polysulfide regulation by the zwitterionic barrier toward durable lithium-sulfur batteries. 2020, 142: 3583-3592.
L. F. Nazar. Advances in lithium-sulfur batteries based on multifunctional cathodes and electrolytes. 2016, 1: 16132.
D. Li. Scalable synthesis of ultrathin polyimide covalent organic framework nanosheets for high-performance lithium-sulfur batteries. 2021, 143: 19446-19453.
J. P. Tu. Confining sulfur in integrated composite scaffold with highly porous carbon fibers/vanadium nitride arrays for high-performance lithium-sulfur batteries. 2018, 28: 1706391.
Z. W. Chen. Stringed "tube on cube" nanohybrids as compact cathode matrix for high-loading and lean-electrolyte lithium-sulfur batteries. 2018, 11: 2372-2381.
W. Q. Han. A review of heteroatom doped materials for advanced lithium-sulfur batteries. 2022, 32: 2107166.
B. Li. Design principles for heteroatom-doped nanocarbon to achieve strong anchoring of polysulfides for lithium-sulfur batteries. 2016, 12: 3283-3291.
Z. H. Wei. High-rate, ultralong cycle-life lithium/sulfur batteries enabled by nitrogen-doped graphene. 2014, 14: 4821-4827.
L. F. Nazar. Spherical ordered mesoporous carbon nanoparticles with high porosity for lithium-sulfur batteries. 2012, 51: 3591-3595.
J. Q. Huang. Implanting atomic cobalt within mesoporous carbon toward highly stable lithium-sulfur batteries. 2019, 31: 1903813.
B. G. Lu. 3D holey graphene/polyacrylonitrile sulfur composite architecture for high loading lithium sulfur batteries. 2021, 11: 2100448.
Z. Q. Lin. Carbon/sulfur aerogel with adequate mesoporous channels as robust polysulfide confinement matrix for highly stable lithium-sulfur battery. 2020, 20: 7662-7669.
M. K. Liu. A high-areal-capacity lithium-sulfur cathode achieved by a boron-doped carbon-sulfur aerogel with consecutive core-shell structures. 2019, 55: 1084-1087.
M. S. Hamdy. High-efficiency electrocatalytic NO reduction to NH by nanoporous VN. 2022, 1: e9120022.
C. Zhang. Multi-heteroatom-doped hollow carbon nanocages from ZIF-8@CTP nanocomposites as high-performance anodes for sodium-ion batteries. 2022, 32: 101116.
J. Zeng. A highly efficient metal-free electrocatalyst of f-doped porous carbon toward N electroreduction. 2020, 32: 1907690.
W. Feng. Nitrogen and fluorine co-doped graphene as a high-performance anode material for lithium-ion batteries. 2015, 3: 23095-23105.
Z. F. Liu. Vacancy manipulating of molybdenum carbide MXenes to enhance Faraday reaction for high performance lithium-ion batteries. 2022, 1: e9120026.
J. X. Geng. Three-dimensional porous carbon composites containing high sulfur nanoparticle content for high-performance lithium-sulfur batteries. 2016, 7: 10601.
Z. Q. Lin. Metal-organic frameworks-derived heteroatom-doped carbon electrocatalysts for oxygen reduction reaction. 2021, 86: 106073.
Z. Q. Lin. Closing the anthropogenic chemical carbon cycle toward a sustainable future via CO valorization. 2021, 11: 2102767.
Y. K. Yang. Simultaneously crafting single-atomic fe sites and graphitic layer-wrapped FeC nanoparticles encapsulated within mesoporous carbon tubes for oxygen reduction. 2021, 31: 2009197.
H. Zhang. Robust SnO nanoparticle-impregnated carbon nanofibers with outstanding electrochemical performance for advanced sodium-ion batteries. 2018, 57: 8901-8905.
Y. J. Liu. Metal-coordinated porous polydopamine nanospheres derived FeN-FeCo encapsulated N-doped carbon as a highly efficient electrocatalyst for oxygen reduction reaction. 2022, 1: e9120027.
Z. Q. Lin. A robust solvothermal-driven solid-to-solid transition route from micron SnCO to tartaric acid-capped nano-SnO anchored on graphene for superior lithium and sodium storage
S. Wang. A robust route to Co(OH)CO ultrathin nanosheets with superior lithium storage capability templated by aspartic acid-functionalized graphene oxide. 2019, 9: 1901093.
S. Oswald. On the mechanistic role of nitrogen-doped carbon cathodes in lithium-sulfur batteries with low electrolyte weight portion. 2018, 54: 116-128.
K. Feng. A lithium-sulfur battery using a 2D current collector architecture with a large-sized sulfur host operated under high areal loading and low E/S ratio. 2018, 30: 1804271.
M. Y. Dong. A self-supported 3D aerogel network lithium-sulfur battery cathode: Sulfur spheres wrapped with phosphorus doped graphene and bridged with carbon nanofibers. 2020, 8: 7980-7990.
Y. Yan. Modulating the electronic structure of nanomaterials to enhance polysulfides confinement for advanced lithium-sulfur batteries. 2021, 9: 18927-18946.