All‐solid‐state batteries are promising candidates for the next‐generation safer batteries. However, a number of obstacles have limited the practical application of all‐solid‐state Li batteries (ASSLBs), such as moderate ionic conductivity at room temperature. Here, unlike most of the previous approaches, superior performances of ASSLBs are achieved by greatly reducing the thickness of the solid‐state electrolyte (SSE), where ionic conductivity is no longer a limiting factor. The ultrathin SSE (7.5 µm) is developed by integrating the low‐cost polyethylene separator with polyethylene oxide (PEO)/Li‐salt (PPL). The ultrathin PPL shortens Li+ diffusion time and distance within the electrolyte, and provides sufficient Li+ conductance for batteries to operate at room temperature. The robust yet flexible polyethylene offers mechanical support for the soft PEO/Li‐salt, effectively preventing short‐circuits even under mechanical deformation. Various ASSLBs with PPL electrolyte show superior electrochemical performance. An initial capacity of 135 mAh g−1 at room temperature and the high‐rate capacity up to 10 C at 60 °C can be achieved in LiFePO4/PPL/Li batteries. The high‐energy‐density sulfur cathode and MoS2 anode employing PPL electrolyte also realize remarkable performance. Moreover, the ASSLB can be assembled by a facile process, which can be easily scaled up to mass production.
Polymer electrolytes with high ionic conductivity, good interfacial stability and safety are in urgent demand for practical rechargeable lithium metal batteries (LMBs). Herein we propose a novel flame-retardant polymerized 1,...
Among all the possible anode materials for next-generation rechargeable batteries, lithium (Li) metal stands out from the crowd for its high specific capacity and low redox potential. Unfortunately, the issues caused by Li dendrites limit the commercialization of the batteries based on Li metal anodes. Research in recent years has proved that the Li dendrites cannot be completely eliminated. Inspired by the Chinese legend, "King Yu Tamed the Flood," the new strategy of combing dredge and block, to control the diversion of Li ions is proposed. Via Au modification on one side of the carbon fibers matrix (CFs@Au), selective deposition of Li ions on the back side of the current collector is successfully achieved. This is distant from the separator, and hence improves the safety effectively. As a result, the Coulombic efficiency of the CFs@Au-Li anode remains 99.2% throughout 400 cycles. What is more, the Li-S full cell paired with the composite anode also exhibits outstanding performance, even with limited Li. This backside-deposition strategy provides new insight into safe Li metal anode design for high energy density battery systems such as Li-S and Li-O 2 .
Solid–solid reactions are very effective for solving the main challenges of lithium–sulfur (Li–S) batteries, such as the shuttle effect of polysulfides and the high dependence of electrolyte consumption. However, the low sulfur content and sluggish redox kinetics of such cathodes dramatically limit the practical energy density of Li–S batteries. Here a rationally designed hierarchical cathode to simultaneously solve above‐mentioned challenges is reported. With nanoscale sulfur as the core, selenium‐doped sulfurized polyacrylonitrile (PAN/S7Se) as the shell and micron‐scale secondary particle morphology, the proposed cathode realizes excellent solid–solid reaction kinetics in a commercial carbonate electrolyte under high active species loading and a relatively low electrolyte/sulfur ratio. Such an approach provides a promising solution toward practical lithium sulfur batteries.
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