Electroosmotic Flow Rectification in Membranes with Asymmetrically Shaped Pores: Effects of Current and Pore Density

We have recently demonstrated a new electrokinetic phenomenon—electroosmotic flow rectification in membranes with asymmetrically shaped pores. Flow rectification means that at constant driving force the flow rate in one direction through the membrane is faster than the flow rate in the opposite dire...

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Veröffentlicht in:	Journal of physical chemistry. C 2015-06, Vol.119 (29)
Hauptverfasser:	Bishop, Gregory W., Lopez, Marcos M., Ramiah Rajasekaran, Pradeep, Wu, Xiaojian, Martin, Charles R.
Format:	Artikel
Sprache:	eng
Schlagworte:	Bio-inspired Charge transport Defects Electrical properties Electrodes Electrolytes Electroosmosis Energy storage (including batteries and capacitors) INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY Membranes Synthesis (novel materials) Synthesis (scalable processing) Synthesis (self-assembly)
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container_title	Journal of physical chemistry. C
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creator	Bishop, Gregory W. Lopez, Marcos M. Ramiah Rajasekaran, Pradeep Wu, Xiaojian Martin, Charles R.
description	We have recently demonstrated a new electrokinetic phenomenon—electroosmotic flow rectification in membranes with asymmetrically shaped pores. Flow rectification means that at constant driving force the flow rate in one direction through the membrane is faster than the flow rate in the opposite direction. EOF rectification could be of practical use in microfluidic devices incorporating porous membranes, but additional research is required. As such, we explore here the effects of two key experimental variables—current density used to drive flow through the membrane and membrane pore density—on EOF rectification. We have found that the extent of EOF rectification, as quantified by the rectification ratio, increases with increasing current density. In contrast, the rectification ratio decreases with increasing membrane pore density. We propose explanations for these results based on simple EOF and membrane-transport theories.
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Nanostructures for Electrical Energy Storage (NEES)</creatorcontrib><title>Electroosmotic Flow Rectification in Membranes with Asymmetrically Shaped Pores: Effects of Current and Pore Density</title><title>Journal of physical chemistry. C</title><description>We have recently demonstrated a new electrokinetic phenomenon—electroosmotic flow rectification in membranes with asymmetrically shaped pores. Flow rectification means that at constant driving force the flow rate in one direction through the membrane is faster than the flow rate in the opposite direction. EOF rectification could be of practical use in microfluidic devices incorporating porous membranes, but additional research is required. As such, we explore here the effects of two key experimental variables—current density used to drive flow through the membrane and membrane pore density—on EOF rectification. 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C</jtitle><date>2015-06-02</date><risdate>2015</risdate><volume>119</volume><issue>29</issue><issn>1932-7447</issn><eissn>1932-7455</eissn><abstract>We have recently demonstrated a new electrokinetic phenomenon—electroosmotic flow rectification in membranes with asymmetrically shaped pores. Flow rectification means that at constant driving force the flow rate in one direction through the membrane is faster than the flow rate in the opposite direction. EOF rectification could be of practical use in microfluidic devices incorporating porous membranes, but additional research is required. As such, we explore here the effects of two key experimental variables—current density used to drive flow through the membrane and membrane pore density—on EOF rectification. We have found that the extent of EOF rectification, as quantified by the rectification ratio, increases with increasing current density. In contrast, the rectification ratio decreases with increasing membrane pore density. 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subjects	Bio-inspired Charge transport Defects Electrical properties Electrodes Electrolytes Electroosmosis Energy storage (including batteries and capacitors) INORGANIC, ORGANIC, PHYSICAL, AND ANALYTICAL CHEMISTRY Membranes Synthesis (novel materials) Synthesis (scalable processing) Synthesis (self-assembly)
title	Electroosmotic Flow Rectification in Membranes with Asymmetrically Shaped Pores: Effects of Current and Pore Density
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