Enhancing Electron/Ion
Transport in SnO2 Quantum Dots Decorated Polyaniline/Graphene
Hybrid Fibers for Wearable
Supercapacitors with High Energy Density
posted on 2024-03-26, 15:04authored byXiaoyu Jia, Yuan Du, Fanyu Xie, Hongwei Li, Mei Zhang
Fiber-based supercapacitors are the potential power sources
in
the field of wearable electronics and energy storage textiles due
to their unique advantages of electrochemical properties and mechanical
flexibility, but achieving high energy density and practical energy
supply still presents some challenges. In this study, we reported
an approach of microfluidic assisted wet-spinning to fabricate SnO2 quantum dots encapsulated polyaniline/graphene hybrid fibers
(SnO2 QDs@PGF) by incorporating uniformly polyaniline into
graphene fibers and covalently bridging SnO2 quantum dots.
The assembled SnO2 QDs@PGF fiber-typed flexible supercapacitors
exhibit an ultralarge specific areal capacitance of 925 mF cm–2 in PVA/H2SO4, superior rate
capabilities, and capacitance retention of 88% after 8000 cycles,
indicating that the SnO2 QDs@PGF possess near-ideal capacitance
properties, efficient ion transfer rate, and good cycling stability.
In the EMITFSI/PVDF-HFP electrolyte system, SnO2 QDs@PGF
realize a wide operating potential window of 2.5 V, a specific areal
capacitance of 678.4 mF cm–2, and an energy density
of 147.2 μWh cm–2 at 500 μW cm–2, which can be utilized to power an alarm clock, an electronic timer,
and a desk lamp with a requirement of a 3 V battery. The exceptional
performance of the SnO2 QDs@PGF can be attributed to the
molecular-level homogeneous composite of granular polyaniline and
graphene nanosheets and the interfacial C-O-Sn covalent coupling strategy
employed between SnO2 QDs and PGF. These avenues not only
effectively prevent the undesirable restacking of graphene nanosheets
but also increase the interlayer electroactive sites, ordered ion
diffusion channels, and strong interfacial charge transfer.