Abstract
This study aimed at evaluation of air pollution control residues (APCR) and flue gas desulfurization residues (FGDR) from copper foundry in Southwestern Poland as adsorbents of Cu(II) and Pb(II) from simulated wastewater. Studies of the impact of pH and adsorbent dose, as well as sorption isotherms, and kinetic and thermodynamic studies were conducted in a series of batch experiments. The maximum adsorption capacities were equal to 42.9 mg g−1 Cu(II) and 124.4 mg g−1 Pb(II) for APCR and 98.8 mg g−1 Cu(II) and 124.7 mg g−1 Pb(II) for FGDR, which was comparable to mineral adsorbents examined in other studies. Adsorption isotherms followed the Langmuir model, except for Pb(II) for FGDR, which followed Freundlich model. Sorption kinetics for both materials was properly expressed by pseudo-second-order equation. Mean adsorption energy parameter suggested that the adsorption might have occurred via physical bonding. Thermodynamic study revealed that adsorption was spontaneous and endothermic for Cu(II) and not spontaneous and exothermic for Pb(II), with lower temperature favoring the process. The results suggested that both materials had high affinity towards Cu(II) and Pb(II) ions and could be conducted industrial scale research for consideration as potential adsorbents from aqueous solutions.
Highlights
The increasing human activity and technology development are beneficial for mankind; the environmental conditions, suffer from it more and more visibly
The aim of this study was to verify the feasibility of air pollution control residues (APCR) and flue gas desulfurization residues (FGDR) from copper foundry in Southwestern Poland as adsorbents of Cu(II) and Pb(II) from simulated aqueous solutions
APCR and FGDR powder samples were received from copper smelter in Głogów (Southwestern Poland), where they were sampled directly from individual places of the process
Summary
The increasing human activity and technology development are beneficial for mankind; the environmental conditions, suffer from it more and more visibly. Most cost-effective appears to be adsorption (Bakarat 2011); Environ Sci Pollut Res (2018) 25:31520–31534 many researchers take great efforts in developing low-cost and environment-friendly adsorbents. The outcome of 6 washing cycles was that the adsorption capacity was reduced from 100 to 83%, showing the excellent stability of the adsorbent. The other chemicals used in the regeneration of low-cost adsorbents were alkalized distilled water (pH = 8) for rice husk, which maintained 91% adsorption capacity in the second cycle (Shalaby et al 2017), and H2SO4/NaOH treatment of chitosan, that led to the activation of chitosan, which caused full recovery of adsorption capacity (Schwarz et al 2018)
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