Mathematical Modeling on Ultra-Filtration Using Functionalized Carbon Nanotubes

Yue Chan

doi:10.4028/www.scientific.net/AMM.328.664

Paper Titles

The Simulation Study of the Car Curve Traveling Traction Control System
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Dynamic Identification of Industrial Robots from Low-Sampled Data
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Theoretical Analysis and Experimental Model Study on Stability of a Crack Rotor System
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Effect of Different Silica Source on NaA Nanocrystal
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Mathematical Modeling on Ultra-Filtration Using Functionalized Carbon Nanotubes
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Design of NDR-Based Oscillators Suitable for the Nano-Based BiCMOS Technique
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Fast and Simple Fabrication of RGO/Ag Nanocomposite with Homogenous Dispersion
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Influence of Hole Size on Crack Propagation Mechanism of Nano-Single Crystal Copper
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The Comparative Study of Non-Equilibrium and Equilibrium MD Simulation Results on Gas Flow in Nanopore
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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vol. 328Mathematical Modeling on Ultra-Filtration Using...

Mathematical Modeling on Ultra-Filtration Using Functionalized Carbon Nanotubes

Abstract:

Numerous computational simulations have been performed for the study of the ultra-filtration using carbon nanotubes. However, most carbon nanotubes have dangling bonds at nanotube rims, which severely compromise the validity of such computational simulations. In this paper, we use applied mathematical modeling and the continuous approximation to investigate the acceptance conditions for the water and ions permeating through the functionalized carbon nanotube, and in particular the sodium and chloride ions. Such problem is important for future ion transport and detection. For the nanotube of radius 3.8 Å, while the presence of a tiny positive charge at the nanotube rim will prevent water from entering the nanotube, the presence of a negative charge at the nanotube rim will always enhance the water absorption. With a proper tuning of the total charge at the nanotube entry, we can selectively sieve the sodium or chloride ions. The mathematical framework presented here possesses the merit of delivering deductive and rapid results.