Grafting the surface of carbon nanotubes and carbon black with the chemical properties of hyperbranched polyamines

Controlling the chemistry on the surface of new carbon materials is a key factor to widen the range of their applicability. In this paper we show a grafting methodology of polyalkylamines to the surface of carbon nanomaterials, in particular, carbon nanotubes and a carbon black. The aim of this work...

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Published in:Science and technology of advanced materials 2016-01, Vol.17 (1), p.541-553
Main Authors: Morales-Lara, Francisco, Domingo-García, María, López-Garzón, Rafael, Luz Godino-Salido, María, Peñas-Sanjuán, Antonio, López-Garzón, F. Javier, Pérez-Mendoza, Manuel, Melguizo, Manuel
Format: Article
Language:English
Subjects:
10 Engineering and Structural materials
104 Carbon and related materials
105 Low-Dimension (1D/2D) materials
212 Surface and interfaces
301 Chemical syntheses / processing
502 Electron spectroscopy
Aqueous solutions
Carbon black
Carbon nanomaterials
Carbon nanotubes
Carbonyls
Chelation
Chemical properties
Coordination
Engineering and Structural materials
functionalization
Grafting
hyperbranched polyamines
Metal ions
Nanomaterials
Palladium
Platinum
Polyamines
Titration
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Summary:Controlling the chemistry on the surface of new carbon materials is a key factor to widen the range of their applicability. In this paper we show a grafting methodology of polyalkylamines to the surface of carbon nanomaterials, in particular, carbon nanotubes and a carbon black. The aim of this work is to reach large degrees of covalent functionalization with hyperbranched polyethyleneimines (HBPEIs) and to efficiently preserve the strong chelating properties of the HBPEIs when they are fixed to the surface of these carbon materials. This functionalization opens new possibilities of using these carbon nanotubes-based hybrids. The results show that the HBPEIs are covalently attached to the carbon materials, forming hybrids. These hybrids emerge from the reaction of amine functions of the HBPEIs with carbonyls and carboxylic anhydrides of the carbon surface which become imine and imide bonds. Thus, due to the nature of these bonds, the pre-oxidized samples with relevant number of C=O groups showed an increase in the degree of functionalization with the HBPEIs. Furthermore, both the acid-base properties and the coordination capacity for metal ions of the hybrids are equivalent to that of the free HBPEIs in solution. This means that the chemical characteristics of the HBPEIs have been efficiently transferred to the hybrids. To reach this conclusion we have developed a novel procedure to assess the acid-base and the coordination properties of the hybrids (solids) by means of potentiometric titration. The good agreement of the values obtained for the hybrids and for the free HBPEIs in aqueous solution supports the reliability of the procedure. Moreover, the high capacity of the hybrids to capture Ni 2+ by complexation opens new possibilities of using these hybrids to capture high-value metal ions such as Pd 2+ and Pt 2+ . Hyperbranched polyethylenimines are covalently fixed to the surface of carbon materials, so the chemical characteristics of the amines are transferred to the hybrid materials.
ISSN:1468-6996
1878-5514
DOI:10.1080/14686996.2016.1221728