Abstract:Flexible
and stretchable optoelectronics including organic solar
cells, electronic skins, organic electrochemical transistors, organic
light-emitting diodes, and supercapacitors will play an important
role in our lives in the future. Conductive electrodes with desirable
mechanical properties are the key to achieving those devices with
high performance. Conductive polymers (CPs) have emerged as promising
elastic electrode materials for these unprecedented devices as electrodes,
buffer layers, channels, or inter… Show more
“…selfpowered electronic devices, building or vehicle-integration, space technology, etc. 15,[23][24][25] This requires systematic optimization of the substrate, transparent electrodes, active layers, interfaces, and device structures for OPVs with the desirable mechanical and optoelectronic properties. 26 To bypass the disadvantages of ITO transparent electrodes, a variety of transparent electrodes, e.g.…”
Maximizing the efficiency while exploiting fully inherent advantages of organic photovoltaics (OPVs), e.g., ultra-flexibility, ultra-lightweight, rich color, etc., is of great significance for the commercialization of OPVs. To address it,...
“…selfpowered electronic devices, building or vehicle-integration, space technology, etc. 15,[23][24][25] This requires systematic optimization of the substrate, transparent electrodes, active layers, interfaces, and device structures for OPVs with the desirable mechanical and optoelectronic properties. 26 To bypass the disadvantages of ITO transparent electrodes, a variety of transparent electrodes, e.g.…”
Maximizing the efficiency while exploiting fully inherent advantages of organic photovoltaics (OPVs), e.g., ultra-flexibility, ultra-lightweight, rich color, etc., is of great significance for the commercialization of OPVs. To address it,...
“…Polymeric films, especially with nanoscale thickness, are attracting a tremendous interest due to perspective applications spanning a variety of fields, from environment and energy-related separation/transportation to soft robotics ( Figure 1 ). Ultrathin polymeric films represent ideal functional components of the next-generation membranes for gas separation, 1 desalinization 2 and nanofiltration, 3 thin-film transistors, 4 , 5 wearable sensing devices, 6 long-life high-capacity batteries, 7 and miniaturized soft robots, 8 , 9 , 10 whose efficiency and performance can in principle greatly benefit from thickness reduction down to the nanoscale. Figure 1 Ultrathin polymeric films applications Overview of applications of ultrathin films, such as thin-film transistors (reproduced with permission from Wu et al.…”
Section: Introductionmentioning
confidence: 99%
“… Figure 1 Ultrathin polymeric films applications Overview of applications of ultrathin films, such as thin-film transistors (reproduced with permission from Wu et al. 5 ), soft robotics (reproduced with permission from Schmauch et al. 9 ), energy storage, wearable devices, and separation membranes.…”
“…1−4 In particular, the evolution of high-energy storage devices with lightweight and multifunction remains an enormous challenge. 5 Zinc−air battery is considered the most promising next-generation power system because of its high theoretical specific energy (1086 Wh kg −1 ), abundant resource, and environmental friendliness. 6−8 Several studies devoted to reducing zinc anode dendrites and promoting electrocatalytic efficiency have made significant progress recently.…”
Section: Introductionmentioning
confidence: 99%
“…The growing demand for portable wearable technologies in the information age has inspired extensive research into safe, efficient, and comfortable flexible electronics, especially in mobile health-medical monitoring. − In particular, the evolution of high-energy storage devices with lightweight and multifunction remains an enormous challenge . Zinc–air battery is considered the most promising next-generation power system because of its high theoretical specific energy (1086 Wh kg –1 ), abundant resource, and environmental friendliness. − Several studies devoted to reducing zinc anode dendrites and promoting electrocatalytic efficiency have made significant progress recently. − However, most use alkaline aqueous electrolytes, which are extremely difficult to achieve the all-solid-state and flexibility of zinc–air batteries.…”
Flexible zinc–air batteries have broad potential
as the
next generation of energy storage component in wearable electronic
devices. However, the mechanical performance and ionic conductivity
of electrolytes are urgent issues that hinder the commercial application
of flexible batteries. Herein, the alkaline gel polymer electrolyte
(AGPE) with a double-network structure is developed, which consists
of a covalently cross-linked polyacrylamide (PAM) by in situ polymerization
and a physically cross-linked poly(vinyl alcohol) (PVA) by the freeze–thaw
method. The freestanding PVA/N-PAM/KOH gel electrolyte demonstrates
high ionic conductivity (309.9 mS cm–1) and excellent
mechanical toughness (0.69 MJ m–3), benefiting from
the synergistic effect of the double cross-linked system and hydrogen
bonds. Meanwhile, the assembled ″sandwich″-type zinc–air
battery presents excellent power density (40.43 mW cm–2), long-term cycle life (113 cycles), super-high-energy efficiency
(70.2%), and stable discharge plateau. Impressively, the PVA/N-PAM/KOH-based
batteries attached to the human body surface are reliably capable
of powering light-emitting diodes.
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