Abstract
Lithium polysulphides generated during discharge in the cathode of a lithium-sulphur redox cell are important, but their dissolution into the electrolyte from the cathode during each redox cycle leads to a shortened cycle life. Herein, we use in situ spectroelectrochemical measurements to demonstrate that sp2 nitrogen atoms in the organic linkers of nanocrystalline metal-organic framework-867 (nMOF-867) are able to encapsulate lithium polysulphides inside the microcages of nMOF-867, thus helping to prevent their dissolution into the electrolyte during discharge/charge cycles. This encapsulation mechanism of lithiated/delithiated polysulphides was further confirmed by observations of shifted FTIR spectra for the C = N and C-N bonds, the XPS spectra for the Li-N bonds from nMOF-867, and a visualization method, demonstrating that nMOF-867 prevents lithium polysulphides from being dissolved in the electrolyte. Indeed, a cathode fabricated using nMOF-867 exhibited excellent capacity retention over a long cycle life of 500 discharge/charge cycles, with a capacity loss of approximately 0.027% per cycle from a discharge capacity of 788 mAh/g at a high current rate of 835 mA/g.
Highlights
We found that the high-order polysulphides from the lithiation of the S8 species could be encapsulated inside the microcages of nMOF-867, preventing lithium polysulphide dissolution and extending the cycle life
For nUiO-67, a H2BPDC organic linker was used in place of H2BPYDC in nMOF-867, and all of the other ingredients as well as the heating process were the same as those used for nMOF-867 (Figure S1)
The activated nMOFs were mixed with high-purity sulphur in a mortar in an Ar-filled glove box, and the mixtures were placed in a sealed vessel
Summary
NMOF-867 was prepared by dissolving zirconium chloride (ZrCl4) and H2BPYDC in N,N-dimethylformamide (DMF) in a 20 mL glass vial at room temperature. The effect observed for nUiO-67 was much smaller (Figure S12b) These results imply that the sp[2] nitrogen atoms in the organic linkers of nMOF-867 can encapsulate Li2S4 via chemical interactions, which prevent the dissolution of polysulphide into the electrolyte. The initial colour of Li2S4 was yellow, and this colour was maintained after stirring for 240 min These results provide clear evidence that the colour change was due to chemical interactions between sp[2] nitrogens and lithium polysulphides and not to photooxidation. NUiO-67 exhibited no change in its UV-Vis absorption because the generated polysulphides were dissolved in the electrolyte
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