Abstract
To support a sustainable energy development, CO2 reduction for carbon neutralization and water-splitting for hydrogen economy are two feasible technical routes, both of which require a significant input of renewable energies. To efficiently store renewable energies, secondary batteries will be applied in great quantity, so that a considerable amount of energy needs to be invested to eliminate the waste battery electrolyte pollution caused by heavy metals including Cu2+, Zn2+ and Pb2+. To reduce this energy consumption, the removal behaviors of these ions by using clinoptilolite and zeolite A under 5, 7 and 10 BV h−1 in a fixed-bed reactor were investigated. The used zeolites were then regenerated by a novel NH4Cl solution soaking, coupled with the ultrasonication method. Further characterizations were carried out using scanning electron microscopy, N2 adsorption and desorption test, and wide-angle X-ray diffraction. The adsorption breakthrough curves revealed that the leaching preference of clinoptilolite was Pb2+ > Cu2+ > Zn2+, while the removal sequence for zeolite A was Zn2+ > Cu2+ > Pb2+. The maximum removal percentage of Zn2+ ions for clinoptilolite under 5 BV h−1 was 21.55%, while it was 83.45% for zeolite A. The leaching ability difference was also discussed combining with the characterization results. The fact that unit cell stayed the same before and after the regeneration treatment approved the efficacy of the regeneration method, which detached most of the ions while doing little change to both morphology and crystallinity of the zeolites. By evaluating the pH and conductivity changes, the leaching mechanisms by adsorption and ion exchange were further studied.
Highlights
Accepted: 30 December 2021Sustainable energy development is of key importance to the human society, which is especially the case when facing the fossil fuel depletion and the associated global warming issues
The heavy metal ions leaching performances of natural clinoptilolite and synthesized zeolite A at different flow rates were comprehensively studied in a fixed-bed adsorption column
Among the two zeolites used for adsorption experiments, zeolite A is better for the adsorption of heavy metal ions in water than clinoptilolite
Summary
Sustainable energy development is of key importance to the human society, which is especially the case when facing the fossil fuel depletion and the associated global warming issues. Conventional methods have been used to remove the heavy metal ions from contaminated water, including chemical precipitation [16], electrochemical methods [17], membrane filtration [18] and ion exchange and adsorption These either require extra electricity input or create additional slurry that demands further treatment. Among these methods, ion exchange and adsorption stand out for its considerable treatment capacity, high removal efficiency, fast response and low energy consumption [14,19]. Solutionthis soaking abathing sustainable treatment method with efficiency, low energy consumption for reported waste battery is likely to enhance regeneration which has never been before electrolyte by reusing the zeolites, which will contribute to the achievement of clean water to the best of our knowledge. Consumption and reproduction (goal 12), protecting the life on land (goal 15) as well as the life below water (goal 14) of the 17 Sustainable Development Goals (SDGs)
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