Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films

Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films

In this study, sisal cellulose/magnetite-nanoparticle (Fe3O4 NPs; 0.5, 1.4, and 3.0 g L−1) hybrid films (denoted as FCFe0.5, FCFe1.4, and FCFe3.0, respectively) were prepared by casting, using the solvent system LiCl/DMAc. Sisal was chosen as a cellulose source because it is a fast-growing plant, in...

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Main Authors: Daiana M. Furlan, Daniella Lury Morgado, Adilson J.A. de Oliveira, Ângelo D. Faceto, Daniel A. de Moraes, Laudemir C. Varanda, Elisabete Frollini
Format: Article
Language:English
Published: Elsevier 2019-04-01
Series:Journal of Materials Research and Technology
Online Access:http://www.sciencedirect.com/science/article/pii/S2238785418308998
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spelling doaj-963304a01d0745558f56037baf67daa12020-11-25T03:04:00ZengElsevierJournal of Materials Research and Technology2238-78542019-04-018221702179Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid filmsDaiana M. Furlan0Daniella Lury Morgado1Adilson J.A. de Oliveira2Ângelo D. Faceto3Daniel A. de Moraes4Laudemir C. Varanda5Elisabete Frollini6Macromolecular Materials and Lignocellulosic Fibers Group, Center for Research on Science and Technology of BioResources, Institute of Chemistry of São Carlos, University of São Paulo, São Carlos, São Paulo, BrazilMacromolecular Materials and Lignocellulosic Fibers Group, Center for Research on Science and Technology of BioResources, Institute of Chemistry of São Carlos, University of São Paulo, São Carlos, São Paulo, BrazilPhysics Department, Federal University of São Carlos, São Carlos, São Paulo, BrazilPhysics Department, Federal University of São Carlos, São Carlos, São Paulo, BrazilColloidal Materials Group, Center for Research on Science and Technology of BioResources, Institute of Chemistry of São Carlos, University of São Paulo, São Carlos, São Paulo, BrazilColloidal Materials Group, Center for Research on Science and Technology of BioResources, Institute of Chemistry of São Carlos, University of São Paulo, São Carlos, São Paulo, BrazilMacromolecular Materials and Lignocellulosic Fibers Group, Center for Research on Science and Technology of BioResources, Institute of Chemistry of São Carlos, University of São Paulo, São Carlos, São Paulo, Brazil; Corresponding author.In this study, sisal cellulose/magnetite-nanoparticle (Fe3O4 NPs; 0.5, 1.4, and 3.0 g L−1) hybrid films (denoted as FCFe0.5, FCFe1.4, and FCFe3.0, respectively) were prepared by casting, using the solvent system LiCl/DMAc. Sisal was chosen as a cellulose source because it is a fast-growing plant, in contrast to the long cycle of woody trees, and Brazil accounts for most of the sisal produced in the world. Fe3O4 NPs were chosen owing to their excellent properties (superparamagnetic behavior at room temperature, high chemical stability, and low toxicity). The synthesized magnetite NPs (coated with oleic acid and oleylamine to prevent agglomeration during synthesis) were spherical with an average diameter of 5.1 ± 0.5 nm (transmission electron microscopy analysis; TEM). X-ray diffraction analysis showed that the NPs were satisfactorily incorporated into the cellulose films (as confirmed by TEM) and that their presence favored the formation of cellulose crystalline domains. FCFe1.4 and FCFe3.0 exhibited higher tensile strengths (14.3 MPa and 12.1 MPa, respectively) than the neat cellulose film (9.9 MPa). The moduli of elasticity of FCFe0.5, FCFe1.4, and FCFe3.0 were 1650, 1500 MPa, and 780 MPa, respectively, lower than that of the cellulose film (1860 MPa), indicating that the incorporation of NPs in the cellulosic matrix decreased the films’ stiffness. Hybrid films exhibited high magnetizations at 300 K, i.e., 23.0 emu g−1 (FCFe0.5), 31.0 emu g−1 (FCFe1.4), and 37.0 emu g−1 (FCFe3.0), as well as no magnetic hysteresis and remanent magnetization (Mr) null, namely, a superparamagnetic behavior at room temperature. The results obtained suggest several applications of hybrid films based on cellulose and magnetite, such as biomedical applications, miniaturized electronic devices, and advanced catalysis. Keywords: Sisal cellulose, Magnetite nanoparticles, Magnetic hybrid filmshttp://www.sciencedirect.com/science/article/pii/S2238785418308998
collection DOAJ
language English
format Article
sources DOAJ
author Daiana M. Furlan
Daniella Lury Morgado
Adilson J.A. de Oliveira
Ângelo D. Faceto
Daniel A. de Moraes
Laudemir C. Varanda
Elisabete Frollini
spellingShingle Daiana M. Furlan
Daniella Lury Morgado
Adilson J.A. de Oliveira
Ângelo D. Faceto
Daniel A. de Moraes
Laudemir C. Varanda
Elisabete Frollini
Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
Journal of Materials Research and Technology
author_facet Daiana M. Furlan
Daniella Lury Morgado
Adilson J.A. de Oliveira
Ângelo D. Faceto
Daniel A. de Moraes
Laudemir C. Varanda
Elisabete Frollini
author_sort Daiana M. Furlan
title Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
title_short Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
title_full Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
title_fullStr Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
title_full_unstemmed Sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
title_sort sisal cellulose and magnetite nanoparticles: formation and properties of magnetic hybrid films
publisher Elsevier
series Journal of Materials Research and Technology
issn 2238-7854
publishDate 2019-04-01
description In this study, sisal cellulose/magnetite-nanoparticle (Fe3O4 NPs; 0.5, 1.4, and 3.0 g L−1) hybrid films (denoted as FCFe0.5, FCFe1.4, and FCFe3.0, respectively) were prepared by casting, using the solvent system LiCl/DMAc. Sisal was chosen as a cellulose source because it is a fast-growing plant, in contrast to the long cycle of woody trees, and Brazil accounts for most of the sisal produced in the world. Fe3O4 NPs were chosen owing to their excellent properties (superparamagnetic behavior at room temperature, high chemical stability, and low toxicity). The synthesized magnetite NPs (coated with oleic acid and oleylamine to prevent agglomeration during synthesis) were spherical with an average diameter of 5.1 ± 0.5 nm (transmission electron microscopy analysis; TEM). X-ray diffraction analysis showed that the NPs were satisfactorily incorporated into the cellulose films (as confirmed by TEM) and that their presence favored the formation of cellulose crystalline domains. FCFe1.4 and FCFe3.0 exhibited higher tensile strengths (14.3 MPa and 12.1 MPa, respectively) than the neat cellulose film (9.9 MPa). The moduli of elasticity of FCFe0.5, FCFe1.4, and FCFe3.0 were 1650, 1500 MPa, and 780 MPa, respectively, lower than that of the cellulose film (1860 MPa), indicating that the incorporation of NPs in the cellulosic matrix decreased the films’ stiffness. Hybrid films exhibited high magnetizations at 300 K, i.e., 23.0 emu g−1 (FCFe0.5), 31.0 emu g−1 (FCFe1.4), and 37.0 emu g−1 (FCFe3.0), as well as no magnetic hysteresis and remanent magnetization (Mr) null, namely, a superparamagnetic behavior at room temperature. The results obtained suggest several applications of hybrid films based on cellulose and magnetite, such as biomedical applications, miniaturized electronic devices, and advanced catalysis. Keywords: Sisal cellulose, Magnetite nanoparticles, Magnetic hybrid films
url http://www.sciencedirect.com/science/article/pii/S2238785418308998
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