In our work, we investigated the EMD second-electron reaction in an electrolyte-lean T-cell system, with very little excess electrolyte. We compared EMD performance in the T-cell with its performance in the electrolyte-flooded beaker cell system at different cycling rates in both KOH and NaOH electrolytes. We found a huge improvement in the stability of EMD when cycled in the electrolyte-lean T-cells especially with NaOH electrolyte (Fig. 1a). We also explored the influence of different carbon materials, including multi-walled carbon nanotube (MWCNT), graphite and Super P carbon blacks in the electrolyte-lean system (Fig. 1b). Different carbon materials were found to have a great impact on both capacity and cycling stability performance of the EMD cathode, possibly due to differences in the specific surface area and the pore sizes of the carbon materials. Electrodes with higher EMD loading and chemically synthesized Bi-doped birnessite material were also tested in the T-cell system to find a more economically favorable electrode composition. Scanning electron microscopy, X-ray diffractions, and other techniques were used to evaluate the phase change and morphology difference during the cycling process.

Figure 1. (a) Comparison between T-cells with 37 wt.% KOH with 21 wt.% NaOH as electrolyte with a normal beaker cell with 37 wt.% KOH electrolytes. The electrodes composed of 60 wt.% EMD, 12 wt.% Bi₂O₃, 14 wt.% Cu, 10 wt.% MWCNT and 4 wt.% PTFE, NiOOH were used as anodes. The C-rate of all tests is C/3. (b) Comparison between different carbon material materials that used in the electrode in T-cells. The electrodes composed of 60 wt.% EMD, 12 wt.% Bi₂O₃, 14 wt.% Cu, 10 wt.% carbon material and 4 wt.% PTFE, NiOOH were used as anodes and 30 wt.% NaOH was used as electrolyte. The C-rate of all tests is C/3.

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