Abstract
Sodium oxalate (Na2C2O4), a green, cost-effective, and high-capacity additive candidate, suffers from a decomposition voltage that largely exceeds the cutoff voltage of currently common layered oxides and polyanionic compounds, limiting its availability. This work constructs a composite structure of carbon-coated Na2C2O4 coupled with a catalyst-loaded Ketjen black (NCO@C@MMNKB) using a low-temperature carbon-coated assisted ball milling technique. The results show that the decomposition potential of Na2C2O4 is significantly reduced from 4.42 to 3.91 V. Meanwhile, the full cell energy density is enhanced from 135.0 to 236.4 Wh Kg−1. Further investigations show that the by-products of the sodium compensation additive exhibit different “gas effects” on the formation of the cathode and anode solid electrolyte interphase (CEI and SEI) films. This provides a practical thought to promote similar additives towards practicality to improve the overall performance of SIBs.
Published Version
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