Flexible textile-based supercapacitors (SCs) have attracted
a lot of attention, with the artificial intelligence technology and
smart wearable electronic textiles developing rapidly. However, energy-storage
performance of common textile-based SCs is always restricted with
the low-dimensional substrates (i.e., one-dimensional fibers or two-dimensional
fabrics), and hence flexible textile-based SCs with multifarious hierarchical
substrates are highly desired. Herein, a multidimensional hierarchical
fabric electrode model with a bionic fiber microarray structure has
been designed, inspired by the “grasp effect” of the
sophisticated arrangement structures of hedgehog spines, and the bionic
assembled SCs exhibit an enhanced specific areal capacitance (245.5
mF/cm2 at 1 mV/cm2), compared with the planar
fabric-based SCs (41.6 mF/cm2), and a high energy density
(21.82 μWh/cm2 at 0.4 mW/cm2). Besides,
the SCs also show a stable capacitance ratio of 83.9% after 10 000
cycles and a mere capacitance loss under different bending states.
As a proof of concept, an all-fabric smart electronic switch is fabricated
with self-power and wearable properties, along with some other trial
applications. Such a hierarchical fabric with a bionic fiber microarray
structure is believed to enhance the performance of the assembled
SCs. We foresee that the multidimensional hierarchical fabric would
bring more promising prospects for flexible textile-based energy-storage
systems and be used in smart wearable textile applications.
Flexible fiber-based Zn-ion batteries
represent an ideal power
platform for smart wearable energy textiles featuring safety, flexibility,
and unique integration. However, the inevitably low elongation limits
(<400%) of common fiber-based Zn-ion batteries may restrict applications
in highly deformable wearable materials and lead to unstable energy
storage performance during practical activities. Herein, an elastic
graphene/polyaniline-Zn@silver fiber-based battery (eG/P-Zn@SFB) with
a helical structure inspired by the biological structure of luffa
tendril is reported. eG/P-Zn@SFB exhibits ultrastretching properties
and can be stretched to 900% with a 71% capacity retention ratio.
Moreover, the prefabricated battery delivers a high specific capacity
of 32.56 mAh/cm3 at 10 mA/cm3 and an energy
density of 36.04 mWh/cm3. As a proof of concept, the knitted
integrated eG/P-Zn@SFB served as an effective power supply with different
bending angles ranging from 0° to 180°, demonstrating potential
applications and promising prospects in stretchable flexible electronics
and wearable energy textiles.
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