With a theoretical capacity of 1166 mA路h路g
鈥?,
lithium sulfide (Li
2S) has received much attention as a promising cathode material for high specific energy
lithium/sulfur cells. However, the insulating nature of Li
2S prevents the achievement of high uti
lization (or high capacity) and good rate capabi
lity. Various efforts have been made to ame
liorate this problem by improving the contact between Li
2S and electronic conductors. In the
literature, however, a relatively high capacity was only obtained with the Li
2S content below 50 wt %; therefore, the estimated cell specific energy values are often below 350 W路h路kg
鈥?, which is insufficient to meet the ever-increasing requirements of newly emerging technologies. Here, we report a cost-effective way of preparing nanostructured Li
2S-carbon composite cathodes by high-energy dry ball mil
ling of commercially available micrometer-sized Li
2S powder together with carbon additives. A simple but effective electrochemical activation process was used to dramatically improve the uti
lization and reversibi
lity of the Li
2S鈥揅 electrodes, which was confirmed by cyc
lic voltammetry and electrochemical impedance spectroscopy. We further improved the cyc
ling stabi
lity of the Li
2S鈥揅 electrodes by adding multiwalled carbon nanotubes to the nanocomposites. With a very high specific capacity of 1144 mA路h路g
鈥? (98% of the theoretical value) obtained at a high Li
2S content (67.5 wt %), the estimated specific energy of our cell was 610 W路h路kg
鈥?, which is the highest demonstrated so far for the Li/Li
2S cells. The cells also maintained good rate capabi
lity and improved cycle
life. With further improvement in capacity retention, nanostructured Li
2S鈥揅 composite cathodes may offer a significant opportunity for the development of rechargeable cells with a much higher specific energy.
Keywords:
Energy storage; lithium%2Fsulfur+batteries&qsSearchArea=searchText">lithium/sulfur batteries; lithium+sulfide+%5C%28Li2S%5C%29&qsSearchArea=searchText">lithium sulfide (Li2S); cathodes; high specific energy; electrochemical activation