Herein, we report the fabrication of a smart wire-shaped flexible and rechargeable Zn-ion battery with shape memory function, which enables the battery to restore the shape and energy storage capability against mechanical deformation by the temperature triggered shape memory effect. As an energy storage device, the flexible wire battery
DOI: 10.1039/C6TA07868K Corpus ID: 99550569; Application of carbon fibers to flexible, miniaturized wire/fiber-shaped energy conversion and storage devices @article{Cai2017ApplicationOC, title={Application of carbon fibers to flexible, miniaturized wire/fiber-shaped energy conversion and storage devices}, author={Xin Cai and Chaoqun
(Inset (f) shows the energy storage performance of the wire-shaped SC as the wearable energy storage device). In order to estimate the charge storage process of the assembled wire-shaped SC, the diffusion-limited and capacitive-controlled processes in the total capacitance contribution were conducted in detail (Fig. 7 (a) and (b)). The
The emerging wire-shaped supercapacitors (WSSs) have motivated tremendous research interests in energy storage devices. However, challenges still exist in the pursuit of high-rate performance WSS. Here, a graphene fiber made from chemical vapor deposition grown laminated graphene sheet is adopted to form a WSS which exhibits an exceptional rate
Flexible fiber-shaped energy storage devices: principles, progress, applications and challenges. Jing Ren 1, Quanfu Xu 1 and Yi-Gang Li 1. [20] Cai X, Zhang C Q, Zhang S S, Fang Y P and Zou D C 2017 Application of carbon fibers to flexible, miniaturized wire/fiber-shaped energy conversion and storage devices J. Mater. Chem.
Viewed from the practical use of wearable electronics, wire-shaped energy storage devices are expected to hold high energy capacity and to maintain their electrochemical performance even under extremely challenging
Demand increasing for next generation portable and miniaturized electronics has aroused much interest to explore microscale and lightweight energy storage devices. Herein, we demonstrate successful development of flexible wire-shaped micro-supercapacitors (micro-SCs) based on novel CoNi2S4/E-NZP film@Cu wire electrode. The etched Ni–Zn–P (E-NZP) film
Wire-shaped supercapacitors, a new class of energy storage devices, have recently received enormous attention advantages of miniature size, lightweight and high flexibility. However, most of the reported wire-shaped supercapacitors are still suffered from low specific capacitance and limited energy densities as well as the relatively poor
Application of carbon fibers to flexible, miniaturized wire/fiber-shaped energy conversion and storage devices CF-based wire/fiber energy devices including fiber nanogenerators, wire/fiber solar cells, wire-type batteries, fiber supercapacitors and integrated/hybrid fiber devices are discussed. Aiming to motivate more exciting applications
A novel all-solid-state, coaxial, fiber-shaped asymmetric supercapacitor has been fabricated by wrapping a conducting carbon paper on a MnO2-modified nanoporous gold wire. This energy wire exhibits high capacitance of 12 mF·cm−2 and energy density of 5.4 μW·h·cm−2 with excellent cycling stability. Hierarchical nanostructures and coaxial
Abstract: The emerging one-dimensional wire-shaped supercapacitors (SCs) with structural advantages of low mass/volume structural advantages hold great interests in wearable electronic engineering. Although graphene fiber (GF) has full of vigor and tremendous potentiality as promising linear electrodefor wire-shaped SCs, simultaneously achieving its facile fabrication
However, there are relatively limited researches focused on the applications of CVD-grown graphene-derived fibers for wire-shaped energy storage devices. Herein, we firstly attempted to explore the GF to be used as the cathodic material to build novel flexible WSAIB with high performance. Instead of traditional spinning GF from solution of
In addition, wire-shaped energy storage devices are easier to integrate with commercial textile fabrics, making them preferable candidates for smart electronics and deformable microsystems, particularly for the wearable, textile-based applications . Viewed from the practical use of wearable electronics, wire-shaped energy storage devices are
The symmetric wire-shaped supercapacitor composed of CNT–MnO2 fiber electrodes and a PVA/H3PO4 electrolyte possesses an energy density of 86 nWh/cm and good cycling performance. Combined with its light weight and high flexibility, this CNT-based wire-shaped supercapacitor shows promise for applications in flexible and wearable energy storage
Wearable fiber-shaped integrated energy conversion and storage devices have attracted increasing attention, but it remains a big challenge to achieve a common fiber electrode for both energy conversion and storage with high performance. Here, we grow aligned carbon nanotubes (CNTs) array on continuous graphene (G) tube, and their seamlessly connected
Synthesis of high-performance TiN based battery-type wire supercapacitors and their energy storage mechanisms. Author links open overlay panel Mingyu Ma a 1, Hao Zhao b 1, Yan Li a, Schematic diagram of the wire-shaped battery-supercapacitor (with photos i, flexibility, ii, lighting a LED bulb, iii, detail of the double helix structure), (b
Herein, we report the fabrication of a smart wire-shaped flexible and rechargeable Zn-ion battery with shape memory function, which enables the battery to restore the shape and energy storage
Benefiting from high flexibility and weavability, the wire-shaped supercapacitors (SCs) arouse tremendous interests for the applications in wearable/portable electronics. Graphene fiber (GF) is considered as a promising linear electrode for wire-shaped SCs. However, the bottleneck is how to develop the GF-based linear electrode with facile fabrication process
Therefore, the OCNTF/3D-rGO substrates could improve the utilization of MnO 2 and promote the reaction kinetics during charge storage. As such, the as-fabricated wire-shaped, all-solid-state FASC device by assembling an OCNTF/3D-rGO/MnO 2 as the cathode and an OCNTF/3D-rGO/Fe 2 O 3 as the anode with the carboxymethyl cellulose sodium
The unique wire-shaped structure makes it possible for the wire-shaped microsupercapacitors to be woven into various textiles and connected in series or parallel to
Abstract. Wire-shaped flexible supercapacitors (FSCs) have attracted tremendous attention due to their tiny volume, lightweight, high flexibility, and wearability. In
Flexible wire shaped energy storage devices grab tremendous attention due to the emergence of wearable and portable electronics markets. Herein, the design principles (fabrication and assembly
The wearable all-solid hybrid power textile has a single-layer interlaced structure, which is a mixture of two polymer-wire-based energy harvesters, including both a
Wire batteries involving various electrode arrangements in fiber-shaped energy storage devices can be classified into five categories: co-axial, parallel, twisted, coiled, and rolled. Among them, co-axial geometry consisting of inner and outer electrodes arranged on the same axis has been widely investigated.
Li–O2 batteries feature extremely high energy density, making their wire-shaped devices a promising candidate for wearable energy-storage application. However, it is a major challenge to explore industrially feasible electrodes for this type of linear batteries. Herein, for the first time, we have demonstrated an effective strategy to fabricate a feasible electrode on a
Abstract Wire-shaped supercapacitors, a new class of energy storage devices, have recently received enormous attention advantages of miniature size, lightweight and high flexibility. However, most of the reported wire-shaped supercapacitors are still suffered from low specific capacitance and limited energy densities as well as the relatively poor electrochemical
Herein, we report the fabrication of a smart wire-shaped flexible and rechargeable Zn-ion battery with shape memory function, which enables the battery to restore the shape and energy
The ever-growing development of flexible and wearable electronics boosts the research on flexible and wearable energy storage devices. However, these devices are susceptible to mechanical deformation, leading to inevitable damage and degradation of performances. Herein, we report the fabrication of a smart wire-shaped flexible and
The symmetric wire-shaped supercapacitor composed of CNT–MnO2 fiber electrodes and a PVA/H3PO4 electrolyte possesses an energy density of 86 nWh/cm and good cycling performance. Combined with its light
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