Vol. 20 No. 3 (2017) Cover Image
Vol. 20 No. 3 (2017)

Published: June 30, 2017

Pages: 744-750

Articles

Adsorption of Copper Ions from Aqueous Solution Using Raw and Modified Can Papyrus: Experimental and Kinetic Study

Usama Akram Saed 1 Noor Sabah A. Jaleel
1 Chemical Eng. Dep. Al-Nahrain University
History
  • Received: February 28, 2017
  • Available Online: June 14, 2017

Abstract

The adsorptions of copper ions from aqueous solution by can papyrus were studied using batch and continuous adsorption. It has been improved surface area and efficiency of the cane papyrus using urea and thiurea at different concentrations through stirring in period of time with mixer. Results proved that cane papyrus very well in the adsorption of metal through the study of important variables and influences such as the contact time, pH in addition to the initial concentration. It was found that the effect of pH at 6 to 7 better than acid or base solution also found that the best time for adsorption to reach equilibrium is 90min and there is no effect of temperature significantly on the results observed, studied the effect of weight of the cane where found that 0.4g best weight. After treatment with urea and thiurea the results improved from the 56% removal by natural cane, 61% for urea modified and 68% for thiurea modified. For continuous adsorption the results shows that when the flow rate increase in constant bed of adsorbent the breakthrough decrease. As well as the best curve was obtained using a cane modified with thiurea weighing 2.5g in a continuous flow rate where the breakthrough curve is start from 25min to 175min. The results was applied to Langmuir and Freundlich adsorption isotherms, the results fitted will to both at correlation coefficients 0.971 and 0.9066 for Langmiur and Freundlich respectively. Pseudo second order was applied and gives better results for adsorption where R2 is 0.9941 while for pseudo first order R2 is 0.136.

Keywords

References

  1. Bailey, S. E., Olin, T. J., Bricka R. M. and Adrian, D. D., (1999) A review of potentially low-cost sorbents for heavy metals‖, Water Research, 33, 2469-2479
  2. Cheung, C. W., Porter J. F. and McKay, G.,‖ (2001) Sorption kinetic analysis for the removal of cadmium ions from effluents using bone char‖, Water Research, 35, 605-621.
  3. Dorris K L, Zhang Y, Shukla A et al. (2000) The removal of heavy metal from aqueous solution by sawdust adsorption removal of copper‖,hazared mater, b80;33-42.
  4. Patil Kishor P, Patil Vilas S, Nilesh Patil, Motiraya Vijay, (2012) Adsorption of Copper (cu 2+) & Copper (zn2+) Metal Ion from Wastewater by Using Soybean Hulls and Sugarcane Bagasse as Adsorbent‖, International Journal of Scientific Research and Reviews, Vol. 1(2), pg 13-23.
  5. Mukesh Parmar and Lokendra Singh Thakur, (2013) Heavy Metal Cu, Ni and Zn: Toxicity, Health Hazards and their removal techniques by Low Cost Adsorbents: A Short Overview‖, International Journal of Plant, Animal and Environmental Sciences,Vol. 3, pg 143-157.
  6. Wang, X.S., Qin, Y.,. (2005) Equilibrium sorption isotherms of Cu2+ on rice bran. Process biochemistry.
  7. Aksu, Z.,Isoglu, I.A.,. (2005) Removal of copper (II) ions from aqueous solution by bio sorption onto agricultural waste sugar beet pulp. Process biochemistry.
  8. Malkoc, E. and Nuhoglu, Y., (2006) Fixed bed studies for the sorption of chromium (VI) onto tea factory waste. Chemical Engineering Science, , 61, 4363-4372.
  9. Lin, S. H. and Wang, C. S., (2002) Treatment of high-strength phenolic wastewater by a new two-step method, Journal of Hazardous Materials, B90, pp 205-216.
  10. Sulaymon, A. H., and Ahmed, K. W., (2007) Competitive adsorption of furfural and phenolic compounds onto activated carbon in fixed bed column, Environ. Sci. Technol.
  11. Gupta, A., Nanoti, O. and Goswami, A. N., (2001) The removal of furfural from water by adsorption with polymeric resin, Separation Science and Technology, 36, 13, 2835-2844.
  12. Sugashini S. and Meera Sheriffa K. M., (2012) Optimization using central composite design (CCD) for the biosorption of Cr (VI) ions by cross linked chitosan carbonized rice husk (CCACR),‖ Clean Technologies and Environmental Policy.
  13. Han R., Wang Y., Yu W., Zou, Shi, and Liu, (2007) Biosorption of methylene blue from aqueous solution by rice husk in a fixed bed Column‖ Journal of Hazardous Materials, 141, 3,713–718.