Startseite Relationship between acidification factors and methylene blue uptake by Ca-bentonite: optimisation and kinetic study
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Relationship between acidification factors and methylene blue uptake by Ca-bentonite: optimisation and kinetic study

  • Amin Salem EMAIL logo und Mohsen Saghapour
Veröffentlicht/Copyright: 1. Februar 2016
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Chemical Papers
Aus der Zeitschrift Chemical Papers Band 70 Heft 2

This investigation studied the uptake of methylene blue from wastewater by normal and treated bentonites to evaluate the effects of acidification factors on removal efficiency. Hydrochloric, sulphuric and nitric acids were blended in accordance with the response surface methodology to prepare acidic agents. The normal clay was then mixed with the prepared solutions after drying in a laboratory oven. The set-up provided controllable conditions for producing nano-porous powders for which the residence time and temperature were changed. The removal efficiency of the treated powders was assessed by defining an adsorption ratio and determining the optimal composition for acidic agent. Based on the statistical theory and experimental data, nitric acid is a suitable agent for manufacturing porous material to remove methylene blue from wastewater. In addition, the Brunauer–Emmett–Teller method, X-ray diffraction and Fourier transform infrared spectroscopy techniques were applied to identify the structural changes. The experimental data obtained from the batch tests were analysed by a new kinetic model which predicted the data variation with higher regression coefficients and lower relative errors. The proposed procedure can be an important tool in optimising the acidification conditions for manufacturing a nano-porous powder with maximal removal efficiency.

Keywords: bentonite; nano-porous active solid; response surface methodology; adsorption; methylene blue uptake; kinetics

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Received: 2015-5-30
Revised: 2015-7-31
Accepted: 2015-8-3
Published Online: 2016-2-1
Published in Print: 2016-1-1

© 2015 Institute of Chemistry, Slovak Academy of Sciences

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https://doi.org/10.1515/chempap-2015-0195
Schlagwörter für diesen Artikel
bentonite; nano-porous active solid; response surface methodology; adsorption; methylene blue uptake; kinetics

Artikel in diesem Heft

  1. Erratum
  2. Erratum to “Arzugul Muslim, Dilnur Malik, Mehriban Hojiahmat: RAFT polymerization of linear ABC triblock copolymer PtBA-b-PS-b-P2VP and regulation of its hierarchical self-assembly structure in solution”, Chemical Papers 69 (11) 1512-1518 (2015)*
  3. Original Paper
  4. Nanoscale lanthanum oxide catalysts for self-condensation of acetone: preparation via self-assembly on anodic aluminum oxide, structure, and properties
  5. Original Paper
  6. Measuring the three forms of ellagic acid: suitability of extraction solvents
  7. Original Paper
  8. Relationship between acidification factors and methylene blue uptake by Ca-bentonite: optimisation and kinetic study
  9. Original Paper
  10. Reactivity of palladium nanoparticles supported on a microemulsion-based organogel network in supercritical carbon dioxide
  11. Original Paper
  12. Transport of iron ions from chloride solutions using cellulose triacetate matrix inclusion membranes with an ionic liquid carrier
  13. Original Paper
  14. Effect of active acidic compounds on storage stability of coker naphtha
  15. Original Paper
  16. Plant-derived surfactants as an alternative to synthetic surfactants: surface and antioxidant activities
  17. Original Paper
  18. Interaction of metallic zirconium and its alloys Zry-2 and E110 with molten eutectic salt of LiF–NaF–KF containing zirconium fluoride components
  19. Original Paper
  20. Assessment of two prop-2-enamide-based polyelectrolytes as property enhancers in aqueous bentonite mud
  21. Original Paper
  22. A novel triphenylamine-based dye sensitizer supported on titania nanoparticles and the effect of titania fabrication on its optical properties
  23. Original Paper
  24. Synthesis of Fe–Ni–Ce trimetallic catalyst nanoparticles via impregnation and co-precipitation and their application to dye degradation
  25. Original Paper
  26. Iron cross-linked carboxymethyl cellulose–gelatin complex coacervate beads for sustained drug delivery
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