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Organoclay polypropylene nanocomposites under different electric field strengths
Abstract Functionalities of clay-polymer nanocomposites (CPN) are related to the degree of clay particle exfoliation and orientation within the polymer matrix. Exploration of new physical methods for such CPN processing is currently an active field of research. In the present work, organoclay polypropylene nanocomposites were prepared by melt intercalation and subsequently exposed to an electric field (E) and studied in-situ by means of synchrotron X-ray scattering. Experiments were performed both at room temperature, and in the melted state (up to 200°C) and during solidification (cooling down to room temperature). Structural changes and time evolution of the alignment of the layered silicates at different E-field strengths, as well as, the final degree of their orientation is discussed. Despite many efforts, i.e. applying different E-field strengths, frequencies, and temperatures; E-field-induced clay particle exfoliation was not observed. The final state of the solidified sample is a semi-crystalline polymer matrix with embedded aligned clay particles having intercalated morphologies. E-field-assisted control of clay layers exfoliation in polymer matrices remains challenging.
Highlights PP-organoclay nanocomposites prepared by melt intercalation. Nanocomposites under different electric fields. Structural changes and alignment of organoclays. Clay particle exfoliation in electric field was not observed.
Organoclay polypropylene nanocomposites under different electric field strengths
Abstract Functionalities of clay-polymer nanocomposites (CPN) are related to the degree of clay particle exfoliation and orientation within the polymer matrix. Exploration of new physical methods for such CPN processing is currently an active field of research. In the present work, organoclay polypropylene nanocomposites were prepared by melt intercalation and subsequently exposed to an electric field (E) and studied in-situ by means of synchrotron X-ray scattering. Experiments were performed both at room temperature, and in the melted state (up to 200°C) and during solidification (cooling down to room temperature). Structural changes and time evolution of the alignment of the layered silicates at different E-field strengths, as well as, the final degree of their orientation is discussed. Despite many efforts, i.e. applying different E-field strengths, frequencies, and temperatures; E-field-induced clay particle exfoliation was not observed. The final state of the solidified sample is a semi-crystalline polymer matrix with embedded aligned clay particles having intercalated morphologies. E-field-assisted control of clay layers exfoliation in polymer matrices remains challenging.
Highlights PP-organoclay nanocomposites prepared by melt intercalation. Nanocomposites under different electric fields. Structural changes and alignment of organoclays. Clay particle exfoliation in electric field was not observed.
Organoclay polypropylene nanocomposites under different electric field strengths
Rozynek, Zbigniew (author) / Silva, Suédina Maria de Lima (author) / Fossum, Jon Otto (author) / da Silva, Geraldo José (author) / de Azevedo, Eduardo Novais (author) / Mauroy, Henrik (author) / Plivelic, Tomás S. (author)
Applied Clay Science ; 96 ; 67-72
2014-03-18
6 pages
Article (Journal)
Electronic Resource
English
Organoclay polypropylene nanocomposites under different electric field strengths
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