Flexible Asymmetric Microsupercapacitors from Freestanding Hollow Nickel Microfiber Electrodes

Morag, Ahiud; Jelinek, Raz

doi:10.1002/aelm.201800584

Cited by 3 publications

(2 citation statements)

References 55 publications

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“…The MSCs also exhibited good flexibility with a capacity retention of 97 % at a bending degree of 180°. A series of conductive polymers, including PANI, PPy, and polythiophene (PTP), have been explored in combination with graphene for MSC fabrication. Conductive polymers not only enlarge the graphene interlayer distances, but also function as pseudocapacitive components to provide additional capacitance, similar to the roles of many other electrode materials .…”

Section: Planar Mesdsmentioning

confidence: 99%

“…[21] Benefiting from highly pseudocapacitive TP and highly conductive EG, the TP/EG MSCs delivered an areal capacitance of 3.42 mF cm À2 and av olumetric capacitance of 326 Fcm À3 at 10 mV s À1 .A lso, an impressive rate capability up to 1000 Vs À1 was also achieved. The MSCs also exhibited good flexibilityw ith ac apacity retention of 97 %a tabending degree of 1808.As eries of conductive polymers, including PANI, [35,85,86] PPy, [87] and polythiophene (PTP), [88] have been exploredi nc ombination with graphene for MSC fabrication. Conductive polymers not only enlarge the graphene interlayer distances, but also function as pseudocapacitive components to provide additional capacitance, similart ot he roles of many other electrode materials.…”

Section: Sandwich-like Stacked Mscsmentioning

confidence: 99%

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Miniaturized Energy Storage Devices Based on Two‐Dimensional Materials

Jiang

Weng

2019

ChemSusChem

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A growing demand for miniaturized biomedical sensors, microscale self‐powered electronic systems, and many other portable, wearable, and integratable electronic devices is continually stimulating the rapid development of miniaturized energy storage devices (MESDs). Miniaturized batteries (MBs) and supercapacitors (MSCs) were considered to be suitable energy storage devices to power microelectronics uninterruptedly with reasonable energy and power densities. However, in addition to similar challenges encountered with electrode materials in conventional energy storage devices, their performances are also greatly affected by microfabrication technologies, as well as the challenges of how to realize stable and high‐performance MESDs in such a limited footprint area. Benefiting from the unique architectural engineering of two‐dimensional materials and the emergence of precise and controllable microfabrication techniques, the output electrochemical performances of MSCs and MBs are improving rapidly. This minireview summarizes recent advances in MSCs and MBs built from two‐dimensional materials, including electrode/device configuration designs, material synthesis, microfabrication processes, smart function incorporations, and system integrations. An introduction to configurations of the MESDs, from linear fibrous shapes, planar sandwich thin‐film or interdigital structures, to three‐dimensional configurations, is presented. The fundamental influences of the electrode material and configuration designs on the exhibited MB/MSC electrochemical performances are also highlighted.

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Section: Planar Mesdsmentioning

confidence: 99%

Section: Sandwich-like Stacked Mscsmentioning

confidence: 99%

Miniaturized Energy Storage Devices Based on Two‐Dimensional Materials

Jiang

Weng

2019

ChemSusChem

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Polydiacetylene–Perylenediimide Supercapacitors

et al. 2020

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Organic supercapacitors have attracted interest as promising “green” and efficient components in energy storage applications. A polydiacetylene derivative coupled with reduced graphene oxide was employed, for the first time, to generate an organic pseudocapacitance‐based supercapacitor that exhibited excellent electrochemical properties. Specifically, diacetylene monomers were functionalized with perylenediimide (PDI), spontaneously forming elongated microfibers. Following polymerization through UV irradiation, the PDI–polydiacetylene microfibers were interspersed with reduced graphene oxide (rGO), generating a porous electrode material exhibiting a high surface area and facilitating efficient ion diffusion, both essential preconditions for supercapacitor applications. We show that PDI–polydiacetylene has an important role in enhancing the electrochemical properties as a supercapacitor electrode. Besides stabilizing the microporous electrode organization, the delocalized π electrons in both the PDI residues and conjugated network of the polydiacetylene contributed to a significantly higher capacitance (specific capacitance >600 F g−1 at 1 A g−1 current density), longer discharge time, and high power density. The PDI–polydiacetylene‐rGO electrodes were employed in a functional supercapacitor device.

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