Plasticization-enhanced hydrogen purification using polymeric membranes

Haiqing Lin; Elizabeth Van Wagner; Benny D. Freeman; Lora G. Toy; Raghubir P. Gupta

doi:10.1126/science.1118079

Plasticization-enhanced hydrogen purification using polymeric membranes

Haiqing Lin
, Elizabeth Van Wagner
, Benny D. Freeman
, Lora G. Toy
, Raghubir P. Gupta

Department of Chemical and Biological Engineering

University of Texas at Austin
RTI International

Research output: Contribution to journal › Article › peer-review

669 Scopus citations

Abstract

Polymer membranes are attractive for molecular-scale separations such as hydrogen purification because of inherently low energy requirements. However, membrane materials with outstanding hydrogen separation performance in feed streams containing high-pressure carbon dioxide and impurities such as hydrogen sulfide and water are not available. We report highly permeable, reverse-selective membrane materials for hydrogen purification, as exemplified by molecularly engineered, highly branched, cross-linked poly(ethylene oxide). In contrast to the performance of conventional materials, we demonstrate that plasticization can be harnessed to improve separation performance.

Original language	English
Pages (from-to)	639-642
Number of pages	4
Journal	Science
Volume	311
Issue number	5761
DOIs	https://doi.org/10.1126/science.1118079
State	Published - Feb 3 2006

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title = "Plasticization-enhanced hydrogen purification using polymeric membranes",

abstract = "Polymer membranes are attractive for molecular-scale separations such as hydrogen purification because of inherently low energy requirements. However, membrane materials with outstanding hydrogen separation performance in feed streams containing high-pressure carbon dioxide and impurities such as hydrogen sulfide and water are not available. We report highly permeable, reverse-selective membrane materials for hydrogen purification, as exemplified by molecularly engineered, highly branched, cross-linked poly(ethylene oxide). In contrast to the performance of conventional materials, we demonstrate that plasticization can be harnessed to improve separation performance.",

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AU - Van Wagner, Elizabeth

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AU - Toy, Lora G.

AU - Gupta, Raghubir P.

PY - 2006/2/3

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N2 - Polymer membranes are attractive for molecular-scale separations such as hydrogen purification because of inherently low energy requirements. However, membrane materials with outstanding hydrogen separation performance in feed streams containing high-pressure carbon dioxide and impurities such as hydrogen sulfide and water are not available. We report highly permeable, reverse-selective membrane materials for hydrogen purification, as exemplified by molecularly engineered, highly branched, cross-linked poly(ethylene oxide). In contrast to the performance of conventional materials, we demonstrate that plasticization can be harnessed to improve separation performance.

AB - Polymer membranes are attractive for molecular-scale separations such as hydrogen purification because of inherently low energy requirements. However, membrane materials with outstanding hydrogen separation performance in feed streams containing high-pressure carbon dioxide and impurities such as hydrogen sulfide and water are not available. We report highly permeable, reverse-selective membrane materials for hydrogen purification, as exemplified by molecularly engineered, highly branched, cross-linked poly(ethylene oxide). In contrast to the performance of conventional materials, we demonstrate that plasticization can be harnessed to improve separation performance.

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Plasticization-enhanced hydrogen purification using polymeric membranes

Abstract

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