Abstract
Clinoptilolite is used as an adsorbent to remove heavy metal cations due to its function as a molecular sieve. This molecular sieve characteristic has made it possible to study the efficiency of clinoptilolite and D-Penicillamine in a comparative way in terms of the adsorption of heavy metals (especially copper) from a biological medium. For this purpose, clinoptilolite was subjected to grinding to produce a homogenized micronized powder in two sizes with d90=75 and 150 μm. Then, initial adsorption tests in an aqueous medium were performed on 10 ppm solutions of iron, zinc, copper, cadmium and nickel cations in single cation solutions, as well as a mixture of cations. In the next step, tests were performed to evaluate the adsorption of Cu2+ on clinoptilolite under different conditions. Experiments have been performed to investigate the effect of pH, temperature (T), adsorbent dosage, time and cation concentration in a simulated biological medium. According to the results, clinoptilolite has a high ability to remove metal cations from aqueous solutions. The 99.71% removal of copper cations by clinoptilolite indicates the high ability of this mineral to remove copper from any environment. In a simulated biological medium at pH=7 and 5, the copper adsorption rate was 98.18% and 97.45% respectively, which indicates the high ability of zeolite to absorb copper cations under biological conditions. An examination of the mass balance calculations has also shown the ability to replace clinoptilolite with penicillamine; 15 mg of clinoptilolite removes 214 mg of Cu from aqueous solutions, which is equivalent to the formation of copper-penicillamine chelate.
Highlights
The cations of lead, aluminium, mercury, copper, cadmium, nickel and arsenic are toxins from industrial wastewaters and are among the most important and dangerous environmental hazards
Due to the unique characteristics of ion exchange, molecular sieving, adsorption and catalytic properties, the clinoptilolite type of zeolite has the potential to be used in the manufacturing of industrial adsorbents
The study concluded that the studied clinoptilolites have a high cation exchange capacity and can absorb cations of metal elements up to 99% from aquatic environments
Summary
The cations of lead, aluminium, mercury, copper, cadmium, nickel and arsenic are toxins from industrial wastewaters and are among the most important and dangerous environmental hazards. Due to their resilience and accumulation in living tissues, toxicity and interference with the food chain, these metals may be transmitted to living organisms and to humans through various ecosystems and cause detrimental effects on human health (Raikwar et al, 2008). Zeolite (with the general chemical formula ) is an aluminosilicate mineral, whose major commercial application in industry is surface adsorbent This group of minerals, due to their special properties, such as porosity, molecular adsorption and cation exchange capacity internally and externally, are widely used in the water treatment industry as catalysts, as well as in the medical and agricultural industries.
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