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Formation and cleaning function of physically cross-linked dual strengthened water-soluble chitosan-based core-shell particles
- Dong, Yanrui, Xiao, Congming
- International journal of biological macromolecules 2017 v.102 pp. 130-135
- Fourier transform infrared spectroscopy, adsorption, aqueous solutions, carbon dioxide, chitosan, cleaning, copper, crosslinking, ethanol, freezing, heavy metals, hydrogels, ions, lead, particulates, polyvinyl alcohol, sodium alginate, sorbents, storage modulus, thawing, thermal stability, thermogravimetry, toxic substances
- Facile and mild ionic cross-linking and freezing/thawing technologies were applied to prepare double strengthened core-shell particles by using water-soluble chitosan (WSC), sodium alginate (SA) and poly(vinyl alcohol) (PVA) as starting materials. The aqueous solution contained WSC and PVA was dropped in ethanol to form beads. The beads were converted into WSC/PVA hydrogel particles by being subjected to three freeze/thaw cycles. Subsequently, ionic cross-linked hydrogel layer was formed around each WSC/PVA particle to generate core-shell particulates. Fourier transform infrared spectra confirmed the combination among various components. Dynamic mechanical thermal analysis indicated that the storage modulus of the core-shell hydrogel was improved obviously. Thermogravimetric analysis exhibited the thermal stability of the particles was also enhanced by incorporation of PVA. It was found that the particles were able to adsorb carbon dioxide, lead ion and copper ion. The adsorption capacities of dry particles toward carbon dioxide, Pb(II) and Cu(II) could reach 199.62, 39.28 and 26.03mg/g, respectively. The rates of the particles for binding Pb(II) and Cu(II) at initial stage were 26.57 and 4.30%/min, respectively. These experimental results suggested that the particles were an efficient sorbent for removing hazardous substances such as carbon dioxide and heavy-metal ions.