In a study recently published in Nature Communications, the researchers detail a modular system that integrates hydrochloric acid recovery with chlorine and hydrogen generation, eliminating the need for external electrical input during the electrochemical stage.
The concept builds on diffusion-cell technology already employed industrially for waste acid recycling. Within each power-generation unit, a chloride-rich waste acid feed flows toward a proton-selective membrane, protons diffuse across the membrane, and a permeate stream forms on the opposite side where purified acid is collected while electrons move through an external circuit to power downstream reactions.
A critical enabling component is a sulfonated covalent-organic framework (COF) membrane that supports rapid proton transport while blocking multivalent metal ions, keeping the recovered acid cleaner and reducing performance losses from metal-induced side reactions.
To sustain operation and regulate chloride transport, the system uses a reversible Ag/AgCl redox couple with periodic electrode switching. In stacked configurations with graphite anodes and platinum cathodes as terminal electrodes, the setup drives chlorine and hydrogen evolution in separate compartments.
Tests using simulated waste acid showed that the integrated device achieved chlorine and hydrogen production rates of approximately 150 L m-2 h-1 and ran stably for at least seven days. The team also demonstrated feasibility with simulated desalination wastewater and seawater, although gas output levels were lower than with the model waste acid.
"Waste brines are often viewed as liabilities," said ZHU Chenguang at QIBEBT, first author of the study. "Here, we demonstrate they can serve as both an energy source and a feedstock - recovering acid while producing two high-value gases."
"What distinguishes this system is its compatibility with existing industrial processes, such as diffusion dialysis, which is already used for acid recovery across multiple industries," added Prof. GAO Jun at QIBEBT, corresponding author of the study. "This enhances the technology's scalability and ease of integration into current infrastructure."
The researchers note that the same osmotic-electrochemical coupling principle could extend beyond chlorine production to other brine-based reactions, including ammonia production from nitrate-containing brines, which could create further options for low-carbon chemical manufacturing.
Research Report:Spontaneous chlorine production from chloride-containing brines
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