Andre J. Van Zyl scite author profile

Andre J. Van Zyl

5Publications

34Citation Statements Received

30Citation Statements Given

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Affiliations

Sasol (South Africa), North-West University

Publications

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Development of new ionomer blend membranes, their characterization, and their application in the perstractive separation of alkenes from alkene–alkane mixtures. I. Polymer modification, ionomer blend membrane preparation, and characterization

Kerres¹,

Zyl²

1999

J. Appl. Polym. Sci.

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In this contribution, the synthesis and characterization of novel ion-exchange blend membranes which contain the SO 3 Ag group for the application in the perstractive separation of alkene-alkane mixtures, where the Ag ϩ ion serves as facilitated transport site for the alkene via formation of a pi complex with the alkene double bond, is presented. In this part of the article, the synthesis and characterization of following blend membrane types are described: (1) acid-base blend membranes of ortho-sulfone-sulfonated polysulfone (PSU) with ortho-sulfone-diaminated PSU; (2) blend membranes of ortho-sulfone-sulfonated PSU with unmodified PSU; (3) blend membranes of ortho-sulfone-sulfonated PSU with ortho-sulfone disilylated PSU. The differently modified PSU types were characterized via 1 H nuclear magnetic resonance ( 1 H-NMR). The acid-base blend membranes were characterized via Fourier transfer infrared (FTIR) spectroscopy. It could be indirectly proved that formation of PSU-SO 3 O ϩ H 3 N-PSU ionic crosslinks takes place. Transmission electron microscopy (TEM) investigations of (1) and (2) yielded the results that these blends are inhomogeneous at the microscopic scale. Mechanical stabilization of these blends is accomplished by physical entanglement of the different macromolecules. The blends (3) were macroscopically inhomogeneous due to the strong difference in hydrophilicity of the blend components. Only the blend 90% PSU-SO 3 HO10% PSU[Si(CH 3 ) 3 ] 2 formed a blended membrane.

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Application of new sulfonated ionomer membranes in the separation of pentene and pentane by facilitated transport

Zyl

Kerres

Cui

et al. 1997

Journal of Membrane Science

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Perfluorosulfonate ionomer membranes for separation of petrochemical mixtures

Zyl¹,

Linkov²,

Bobrova³

et al. 1996

J Mater Sci Lett

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Development of new ionomer blend membranes, their characterization, and their application in the perstractive separation of alkenes from alkene-alkane mixtures. I. Polymer modification, ionomer blend membrane preparation, and characterization

Kerres

Zyl

1999

J. Appl. Polym. Sci.

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ABSTRACT:In this contribution, the synthesis and characterization of novel ion-exchange blend membranes which contain the SO 3 Ag group for the application in the perstractive separation of alkene-alkane mixtures, where the Ag ϩ ion serves as facilitated transport site for the alkene via formation of a pi complex with the alkene double bond, is presented. In this part of the article, the synthesis and characterization of following blend membrane types are described: (1) acid-base blend membranes of ortho-sulfone-sulfonated polysulfone (PSU) with ortho-sulfone-diaminated PSU; (2) blend membranes of ortho-sulfone-sulfonated PSU with unmodified PSU; (3) blend membranes of ortho-sulfone-sulfonated PSU with ortho-sulfone disilylated PSU. The differently modified PSU types were characterized via 1 H nuclear magnetic resonance ( 1 H-NMR). The acid-base blend membranes were characterized via Fourier transfer infrared (FTIR) spectroscopy. It could be indirectly proved that formation of PSU-SO 3 O ϩ H 3 N-PSU ionic crosslinks takes place. Transmission electron microscopy (TEM) investigations of (1) and (2) yielded the results that these blends are inhomogeneous at the microscopic scale. Mechanical stabilization of these blends is accomplished by physical entanglement of the different macromolecules. The blends (3) were macroscopically inhomogeneous due to the strong difference in hydrophilicity of the blend components. Only the blend 90% PSU-SO 3 HO10% PSU[Si(CH 3 ) 3 ] 2 formed a blended membrane.

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Influence of oxygen-containing hydrocarbons on the separation of olefin/paraffin mixtures using facilitated transport

Zyl¹,

Linkov²

1997

Journal of Membrane Science

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Andre J. Van Zyl

Development of new ionomer blend membranes, their characterization, and their application in the perstractive separation of alkenes from alkene–alkane mixtures. I. Polymer modification, ionomer blend membrane preparation, and characterization

Application of new sulfonated ionomer membranes in the separation of pentene and pentane by facilitated transport

Perfluorosulfonate ionomer membranes for separation of petrochemical mixtures

Development of new ionomer blend membranes, their characterization, and their application in the perstractive separation of alkenes from alkene-alkane mixtures. I. Polymer modification, ionomer blend membrane preparation, and characterization

Influence of oxygen-containing hydrocarbons on the separation of olefin/paraffin mixtures using facilitated transport

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