Adsorption of bisphenol A by polysulphone membrane

Adsorption has been found to be a very popular phenomenon in removing EDCs with membranes. The results show that adsorption ability of bisphenol A (BPA) on membranes is related to the material, which has the best removal rate by polysulphone. The efficiency of an ultrafiltration membrane (PS-20) to...

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Published in	Desalination Vol. 253; no. 1; pp. 22 - 29
Main Authors	Su-Hua, Wu, Bing-zhi, Dong, Yu, Huang
Format	Journal Article
Language	English
Published	Amsterdam Elsevier B.V 01.04.2010 Elsevier
Subjects	Adsorption Applied sciences Bisphenol A Bonding Chemical engineering Exact sciences and technology Hydrogen bonding Membrane Membrane separation (reverse osmosis, dialysis...) Membranes Pollution Polysulphone Ultrafiltration Polysulphone Bisphenol A Membrane Ultrafiltration Adsorption Membrane separation Organic matter Saturation pH Desorption Retention
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Abstract	Adsorption has been found to be a very popular phenomenon in removing EDCs with membranes. The results show that adsorption ability of bisphenol A (BPA) on membranes is related to the material, which has the best removal rate by polysulphone. The efficiency of an ultrafiltration membrane (PS-20) to remove BPA is examined as a function of solution conditions. Ca 2+ doesn't appear to aid retention by “bridging” membrane and BPA molecule or by screening the charge potential of the membrane. However, the retention of BPA is significantly influenced by pH resulting in a drastic decrease in retention when the solution pH exceeds its pK a value. The presence of NOM decreases the adsorption of BPA onto membrane due to its competitive adsorption onto the limited adsorption capability of the membrane. Adsorption onto the PS-20 membrane is driven both by hydrophobic adsorption and hydrogen bonding as physical and chemical interaction respectively. Whereas, the high desorption ratio shows that BPA–polysulphone bonding is not very strong, the ever decreasing retention versus permeate volume reveals that the exact evaluation of removal efficiency of BPA with ultrafiltration is impossible until the saturation is accomplished.
AbstractList	Adsorption has been found to be a very popular phenomenon in removing EDCs with membranes. The results show that adsorption ability of bisphenol A (BPA) on membranes is related to the material, which has the best removal rate by polysulphone. The efficiency of an ultrafiltration membrane (PS-20) to remove BPA is examined as a function of solution conditions. Ca 2+ doesn't appear to aid retention by “bridging” membrane and BPA molecule or by screening the charge potential of the membrane. However, the retention of BPA is significantly influenced by pH resulting in a drastic decrease in retention when the solution pH exceeds its pK a value. The presence of NOM decreases the adsorption of BPA onto membrane due to its competitive adsorption onto the limited adsorption capability of the membrane. Adsorption onto the PS-20 membrane is driven both by hydrophobic adsorption and hydrogen bonding as physical and chemical interaction respectively. Whereas, the high desorption ratio shows that BPA–polysulphone bonding is not very strong, the ever decreasing retention versus permeate volume reveals that the exact evaluation of removal efficiency of BPA with ultrafiltration is impossible until the saturation is accomplished. Adsorption has been found to be a very popular phenomenon in removing EDCs with membranes. The results show that adsorption ability of bisphenol A (BPA) on membranes is related to the material, which has the best removal rate by polysulphone. The efficiency of an ultrafiltration membrane (PS-20) to remove BPA is examined as a function of solution conditions. Ca2+ doesn't appear to aid retention by "bridging" membrane and BPA molecule or by screening the charge potential of the membrane. However, the retention of BPA is significantly influenced by pH resulting in a drastic decrease in retention when the solution pH exceeds its pKa value. The presence of NOM decreases the adsorption of BPA onto membrane due to its competitive adsorption onto the limited adsorption capability of the membrane. Adsorption onto the PS-20 membrane is driven both by hydrophobic adsorption and hydrogen bonding as physical and chemical interaction respectively. Whereas, the high desorption ratio shows that BPA-polysulphone bonding is not very strong, the ever decreasing retention versus permeate volume reveals that the exact evaluation of removal efficiency of BPA with ultrafiltration is impossible until the saturation is accomplished.
Author	Su-Hua, Wu Bing-zhi, Dong Yu, Huang
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Keywords	Polysulphone Bisphenol A Membrane Ultrafiltration Adsorption Membrane separation Organic matter Saturation pH Desorption Retention
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Snippet	Adsorption has been found to be a very popular phenomenon in removing EDCs with membranes. The results show that adsorption ability of bisphenol A (BPA) on...
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SubjectTerms	Adsorption Applied sciences Bisphenol A Bonding Chemical engineering Exact sciences and technology Hydrogen bonding Membrane Membrane separation (reverse osmosis, dialysis...) Membranes Pollution Polysulphone Ultrafiltration
Title	Adsorption of bisphenol A by polysulphone membrane
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