Freestanding Flexible Li₂S Paper Electrode with High Mass and Capacity Loading for High‐Energy Li–S Batteries

Abstract: rate of active mass and high electrode polarization; ii) the dissolution of sulfur to soluble polysulfides in an organic electrolyte induces severe loss of active mass and notorious shuttle effect; iii) the huge volume change of sulfur (about 80%) upon lithiation/deli thiation results in fast pulverization and failure of the cathode; iv) highly reactive metallic-Li anode pairs with a flammable organic electrolyte to trigger serious safety hazards. The formation of dendrites on metallic-Li anodes during cycling… Show more

“…Such a facile, cost-effective method has attracted the attention of many researchers [42][43][44][45][46][47][48][62][63][64]. rough the above method, Li 2 S can be combined with carbon in various structures by dispersing Li 2 SO 4 in different carbon matrixes.…”

“…e glucose and Li 2 SO 4 mixture was first heated to 600°C for the carbonization, and the Li 2 SO 4 particles were homogeneously distributed in the carbon matrix without turning into Li 2 S. en, the temperature went up to 800°C, and Li 2 SO 4 totally converted into Li 2 S. It is believed that the glucose carbonization can effectively inhibit the growth or aggregation of nano-Li 2 SO 4 , which is the key to form homogeneously distributed Li 2 S-porous carbon composites [43]. More novel structures, such as one-dimensional fibers, two-dimensional sandwich plates, and three-dimensional networks, were also synthesized through the similar method [42,46,47]. e Li 2 S-carbon composites exhibit a broad application prospect in lithium ions batteries because more and more advanced preparation technologies will be developed.…”

Lithium Sulfide as Cathode Materials for Lithium-Ion Batteries: Advances and Challenges

“…Such a facile, cost-effective method has attracted the attention of many researchers [42][43][44][45][46][47][48][62][63][64]. rough the above method, Li 2 S can be combined with carbon in various structures by dispersing Li 2 SO 4 in different carbon matrixes.…”

“…e glucose and Li 2 SO 4 mixture was first heated to 600°C for the carbonization, and the Li 2 SO 4 particles were homogeneously distributed in the carbon matrix without turning into Li 2 S. en, the temperature went up to 800°C, and Li 2 SO 4 totally converted into Li 2 S. It is believed that the glucose carbonization can effectively inhibit the growth or aggregation of nano-Li 2 SO 4 , which is the key to form homogeneously distributed Li 2 S-porous carbon composites [43]. More novel structures, such as one-dimensional fibers, two-dimensional sandwich plates, and three-dimensional networks, were also synthesized through the similar method [42,46,47]. e Li 2 S-carbon composites exhibit a broad application prospect in lithium ions batteries because more and more advanced preparation technologies will be developed.…”

Lithium Sulfide as Cathode Materials for Lithium-Ion Batteries: Advances and Challenges

“…On the sulfur cathode side, around 80% volume expansion upon discharging also brings a challenge for achieving high cycle stability. In contrast, Li 2 S, a fully lithiated cathode with a high theoretical capacity of 1166 mAh g −1 , can not only be coupled with a lithium‐free anode of graphite, tin, silicon, and metal oxides but also circumvent the volume expansion issue. Therefore, Li 2 S cathode is regarded as a promising candidate for new‐generation energy‐dense lithium ion batteries.…”

“…So far, the most challenging problem for these Li 2 S‐based batteries is its high activation potential barrier, which generally leads to a low initial utilization of Li 2 S active materials. Although many efforts have been made to design conductive coating layers or improving the contact between Li 2 S and electrical conductors, it is still hard to completely extract lithium from Li 2 S due to its insulating nature.…”

“…Nevertheless, detrimental effect may occur at such a high cutoff voltage, such as electrolyte decomposition and Al foil corrosion in LiTFSI‐salt‐based electrolyte, which could make the cell failure after a short cycling. On the other hand, nanosizing of particles is considered to be another way to reduce the potential barrier . For example, the activation voltage for Li 2 S particles with tens of nanometer can be reduced to 3.2 V .…”

In Situ Electrochemically Derived Amorphous‐Li₂S for High Performance Li₂S/Graphite Full Cell

Advanced Characterization Techniques in Promoting Mechanism Understanding for Lithium–Sulfur Batteries