Lithium-ion battery recycling pre-processing with electrochemical discharge: Enhancing gas product analysis and pH monitoring

Abstract

Efficient discharge of Lithium-ion Batteries (LIBs) ensures safe recycling. Electrochemical discharge commonly uses NaCl solutions, causing severe corrosion of battery casing and a release of hazardous gases. This work proposes a novel setup to explore a gaseous product formation during electrochemical discharge processes with low gas quantities, in non-corrosive carbonates solutions (Na₂CO₃ and K₂CO₃). Two discharge setups were tested over 120 h: a conventional setup with a single battery completely immersed in the electrolyte; and a novel half-cells setup with two batteries in series, connected through a platinum wire, and partially immersed in the electrolyte. The two setups showed consistent discharge curves and pH trends, without corrosion. After 70 h, the residual voltage of new LIBs (3.8 V) dropped below the safety threshold (2V, 45 ± 1 % of initial voltage for Na₂CO₃ and 50 % ± 1 % for K₂CO₃). H₂ production was observed during the first 11 h for Na₂CO₃ (1722 ± 400 ppm/h) and 9 h for K₂CO₃ (1519 ± 670 ppm/h), with peaks at 2000–2300 ppm/h after 3–5 h while O₂ and CO₂ production was below the detection limit of the detector (0.1 %-vol for O₂, 50 ppm for CO₂). pH trends in the aqueous electrolytes (pH increased from 11.5 to 11.6 to 12.5 ± 0.48 pH units after 3 h in Na₂CO₃, and 12.06 ± 0.06 after 4 h in K₂CO₃) matched H₂ production and the formulation of the hydroxyl ions. The half-cell setup confirmed that H₂ release at negative half-cell, increasing the pH of discharge solution. These results presented a safe method for LIBs discharge, avoiding corrosion and hazardous gases release.