Synthesis and characterization of <scp>UV</scp>‐curable nanocellulose/<scp>ZnO</scp>/<scp>AlN</scp> acrylic flexible films: Thermal, dynamic mechanical and piezoelectric response

Publication date: 4 Ago 2020

JournalSource: OPENALEXOpenAlex type: articleClosed Access
Authors: M.A. Signore, Chiara De Pascali, Donatella Duraccio, Giulio Malucelli, Ambra Fioravanti, Enrico Melissano, Maria Concetta Martucci, Maurizio Masieri, Pietro Siciliano, Luca Francioso

Abstract This work is aimed at fabricating nanocomposites based on zinc oxide (ZnO) nanostructures and nanocellulose dispersed in a UV‐cured acrylic matrix (EC) for application as functional coatings for self‐powered applications. Morphological, thermal, and dynamic mechanical properties of the nanocomposites were characterized by X‐Ray diffractometry (XRD), scanning electron microscopy, and differential scanning calorimetry. The piezoelectric behavior was evaluated in terms of root mean square (RMS) open circuit voltage, at different accelerations applied to cantilever beams. The generated voltage was correlated with ZnO nanostructures morphology, aluminum nitride film integration on the beam and proof mass insertion at the tip. Nitride layer increased the RMS voltage from 1 to 2.4 mV up to 3.9 mV (using ZnO nanoflowers). As confirmed by XRD analyses, the incorporation of ZnO nanostructures into the acrylic matrix favored an ordered structural arrangement of the deposited AlN layer, hence improving the piezoelectric response of the resulting nanocomposites. With proof mass insertion, the output voltage was further increased, reaching 4.5 mV for the AlN‐coated system containing ZnO nanoflowers.

Origin
Journal of Applied Polymer Science
Volume
138
Issue
4
Cited by
5
Legacy ID
d0183e48c5356e677e7def2f03c6fe81
Biblio references
Volume: 138 Issue: 4 Pages: 49731