There
is huge research activity in the development of flexible
and biocompatible piezoelectric materials for next-generation compliant
micro electro-mechanical systems (MEMS) transducers to be exploited
in wearable devices and implants. This work reports for the first
time on the development of flexible Sc
x
Al(1–x)N films deposited by sputtering
technique onto polyimide substrates, assessing their piezoelectricity
and biocompatibility. Flexible Sc
x
Al(1–x)N films have been analyzed in
terms of morphological, structural, and piezoelectric properties.
Sc
x
Al(1–x)N layer exhibits a good surface roughness of 4.40 nm and moderate
piezoelectricity with an extracted effective piezoelectric coefficient
(d
33
eff) value of 1.87 ± 0.06 pm/V, in good agreement with
the diffraction pattern analysis results. Cell viability assay, performed
to study the interaction of the Sc
x
Al(1–x)N films with human cell lines,
shows that this material does not have significant effects on tested
cells. Furthermore, the Sc
x
Al(1–x)N layer, integrated onto a flexible device and analyzed
by bending/unbending measurements, shows a peak-to-peak open-circuit
voltage (V
OC) of 0.32 V and a short-circuit
current (I
SC) of 0.27 μA, with a
generated power of 19.28 nW under optimal resistive load, thus demonstrating
the potential of flexible Sc
x
Al(1–x)N films as active layers for next-generation wearable/implantable
piezoelectrics.