posted on 2012-11-13, 00:00authored byValentina Cauda, Bruno Torre, Andrea Falqui, Giancarlo Canavese, Stefano Stassi, Thomas Bein, Marco Pizzi
We report on the preparation and the piezoelectric properties
of
ultrathin polymeric nanowires in the oriented pores of mesoporous
silica, which are embedded in the channels of a supporting anodic
alumina membrane. Poly(vinylidene difluoride) [PVDF] and its copolymer,
poly(vinylidene difluoride trifluoroethylene) [PVTF], were both confined
to two types of columnar silica mesopores of ∼5 and 10 nm in
diameter. The extreme spatial confinement induces a preferential orientation
of the crystalline domains of the polymer into a ferroelectric phase,
leading to ultrahigh-aspect-ratio nanowires distributed throughout
the templating host, and having up to 60 μm in length, comparable
to the thickness of the hosting alumina. The resulting distributed
array of piezoelectric nanowires are isolated from each other by a
dielectric matrix, facilitating the handling and electrical contacting.
We show, for the first time, that a remarkable piezo-response, in
the absence of any poling or stretching, is obtained upon nanoconfinement
on the PVDF polymer, which, in contrast, does not show any polarization
when in bulk or film form without poling. The piezoelectric behavior
was assessed by a piezo evaluation system (PES) and we visualized
polar nanowire bundles via piezoresponse force microscopy (PFM). This
“nano-structuration” represents a powerful approach,
holding promise for applications for nanoactuators or bioinspired
ciliated sensors with high sensitivity and resolution.