Sorptive removal and recovery of nickel(II) from an actual effluent of electroplating industry: Comparison between Escherichia coli biosorbent and Amberlite ion exchange resin

In Seob Kwak; Sung Wook Won; Sun Beom Choi; Juan Mao; Sok Kim; Bong Woo Chung; Yeoung-Sang Yun

Korean Journal of Chemical Engineering, Vol.28, No.3, 927-932, March, 2011

DOI10.1007/s11814-010-0441-y Export Citation

Sorptive removal and recovery of nickel(II) from an actual effluent of electroplating industry: Comparison between Escherichia coli biosorbent and Amberlite ion exchange resin

In Seob Kwak¹, Sung Wook Won², Sun Beom Choi², Juan Mao¹, Sok Kim², Bong Woo Chung¹, and Yeoung-Sang Yun^{1, 2, †}

¹Department of Bioprocess Engineering and Department of BIN Fusion Technology, Chonbuk National University, Jeonbuk 561-756, Korea
²Division of Semiconductors and Chemical Engineering, Chonbuk National University, Jeonbuk 561-756, Korea

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The removal and recovery of nickel(II) from wastewater of an electroplating factory was investigated using the waste Escherichia coli biomass as the biosorbent. The results were compared with those from using Amberlite IRN-150 as a commercial sorbent resin. The resin showed better performance with a qmax value of 30.48 mg/g compared to 26.45 mg/g for the biomass, as predicted by the Langmuir isotherm model. Kinetic experiments revealed that the biosorption equilibrium was attained within 15 min. In the recycling of the sorbents, the desorption of nickel(II) from Amberlite was only 50%, which is too low for the adsorption performance of the resin to be maintained at an economic level in subsequent cycles. In contrast, the biomass exhibited reasonable adsorption-desorption performance over three repeated cycles. The capability for repeated use of the sorbent over several cycles and for recovery of the metal ions is the main advantage of the waste biomass.

Keywords:Biosorption;Fermentation Waste;Resin;Nickel;Regeneration

[References]

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[2] Selvakumari G, Murugesan M, Pattabi S, Sathishkumar M, Bull. Environ. Contam. Toxicol., 69, 195 (2002)

[3] Mukherjee AL, Environmental Pollution and Health Hazardscauses and control, Golgotia publications, New Delhi (1986)

[4] Parker SP, Encyclopedia of Environmental Science, 2nd Ed. McGraw Hill, New York (1980)

[5] Selatnia A, Madani A, Bakhti MZ, Kertous L, Mansouri Y, Yous R, Miner. Eng., 17, 903 (2004)

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[9] Tanaka A, Huang Y, Yahagi T, Hossain MK, Sato Y, Narita H, Sep. Purif. Technol., 62(1), 97 (2008)

[10] Puranik PR, Paknikar KM, J. Biotechnol., 55, 113 (1997)

[11] Langmuir I, J. American Chem. Soc., 40, 1361 (1918)

[12] Freundlich H, J. Phys. Chem., 57, 385 (1906)

[13] Lagergren S, Svenska BK, Veterskapsakad Handlingar., 24, 1 (1898)

[14] Ho YS, McKay G, Process Biochem., 34(5), 451 (1999)

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[20] Schiewer S and Volesky B, Biosorption processes for heavy metal removal, Environmental Microbe-Metal Interactions, ASM Press, Washington DC (2002)

[21] Vijayaraghavan K, Lee MW, Yun YS, Biochem. Eng. J., 41, 228 (2008)

[22] Doyle FM, Liu ZD, J. Colloid Interface Sci., 258(2), 396 (2003)

[23] Guangyu Y, Thiruvenkatachari V, Water Res., 37, 4486 (2003)

[24] Mustafa I, Colloid Surf. B., 62, 97 (2008)

[25] Padmavathy V, Bioresour. Technol., 99(8), 3100 (2008)

[26] Zhen C, Wei M, Mei H, J. Hazard. Mater., 155, 357 (2008)

[27] Hawari AH, Mulligan CN, Bioresour. Technol., 97(4), 692 (2006)

[28] Al-Qodah Z, Desalination, 196(1-3), 164 (2006)

[29] Ozer A, Ozer D, J. Hazard. Mater., 100(1-3), 219 (2003)

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[32] Vijayaraghavan K, Clean., 36(3), 299 (2008)

[33] Limousin G, Gaudet JP, Charletm L, Szenknect S, Barthes V, Krimissa M, Appl. Geochem., 22, 249 (2007)

[34] Ho YS, Porter JF, McKay G, Water Air Soil Poll., 141, 1 (2002)

[35] McKay G, Ho YS, Ng JCY, Sep. Purif. Methods, 28(1), 87 (1999)

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[37] Iqbal M, Saeed A, Process Biochem., 42, 148 (2007)