Flexible Transparent Supercapacitors: Materials and Devices

Zhao, Weiwei; Jiang, Mengyue; Wang, Weikang; Liu, Shujuan; Huang, Wei; Zhao, Qiang

doi:10.1002/adfm.202009136

Cited by 166 publications

(134 citation statements)

References 304 publications

(293 reference statements)

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“…The areal capacitances calculated from the CV curves were 0.09 mF/cm 2 for the AACS NW electrode and 4.3, 8.7, and 12.2 mF/cm 2 for Ag/Au/MnO 2 core–shell NW electrodes. The areal capacitances were calculated according to

, where

is the current,

and

are the initial and final voltage of the CV curve, ν is the scan rate, and

is the geometric area of the electrode [ 26 ]. To identify the charge-storage mechanism of the suggested Ag/Au/MnO 2 core–shell NW electrode, we conducted additional CV tests in various voltage scan rates, as shown in Figure S9a .…”

Section: Resultsmentioning

confidence: 99%

“…After 500 times repeated bending cycles, the capacitance was maintained at 94%, confirming the mechanical stability and flexibility of the suggested Ag/Au/MnO 2 core–shell NW network electrodes. Finally, we evaluated the performance of the fabricated flexible supercapacitor through a Ragone plot, as shown in Figure 6 d. The energy and power density were calculated according to

and

, respectively [ 26 ]. From the Ragone plot, it was confirmed that the suggested Ag/Au/MnO 2 flexible supercapacitor was able to store 0.41 μWh/cm 2 at 12.9 μW/cm 2 , which is comparable (or even better) to some of the previously reported flexible supercapacitors using various materials such as the MnO 2 /Au (4.2 μWh/cm 2 at 0.51 μW/cm 2 ), the GO/CNT (25.5 nWh/cm 2 at 1.25 μW/cm 2 ), the rGO/Cu-MOF (0.51 μWh/cm 2 at 2.54 μW/cm 2 ), the ZnO NW (0.03 μWh/cm 2 at 14 μW/cm 2 ), and the MnO 2 /Ti3C2Tx MXene (0.7 μWh/cm 2 at 80.0 μW/cm 2 ).…”

Section: Resultsmentioning

confidence: 99%

“…IdV, where I is the current, v i and v f are the initial and final voltage of the CV curve, ν is the scan rate, and A is the geometric area of the electrode [26]. To identify the charge-storage mechanism of the suggested Ag/Au/MnO 2 core-shell NW electrode, we conducted additional CV tests in various voltage scan rates, as shown in Figure S9a.…”

Section: Electrochemical Performances Of the Ag/au/mno2 Core-shell Nw Electrodementioning

confidence: 99%

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Electrodeposition of the MnO2 on the Ag/Au Core–Shell Nanowire and Its Application to the Flexible Supercapacitor

Seo

Kim

et al. 2021

Materials

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Supercapacitors have received considerable attention as energy storage devices owing to their high power density, fast charge/discharge rate, and long cyclic life. Especially with an increasing demand for flexible and wearable devices, research on flexible supercapacitors has surged in recent years. The silver nanowire (Ag NW) network has been used as a flexible electrode owing to its excellent mechanical and electrical properties; however, its use as an electrode for flexible supercapacitors has been limited due to insufficient electrochemical stability. In this study, we proposed a method to resolve this issue. We employed a solution process that enabled the coating of the surface of Ag NW by a thin Au shell of ≈ 5 nm thickness, which significantly improved the electrochemical stability of the Ag NW network electrodes. Furthermore, we confirmed for the first time that MnO2, which is one of the most widely used capacitive materials, can be directly electroplated on the AACS NW network electrode. Finally, we fabricated a high-performance and flexible solid-state supercapacitor using the suggested Ag/Au/MnO2 core–shell NW network electrodes.

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, where

is the current,

and

are the initial and final voltage of the CV curve, ν is the scan rate, and

Section: Resultsmentioning

confidence: 99%

and

Section: Resultsmentioning

confidence: 99%

Section: Electrochemical Performances Of the Ag/au/mno2 Core-shell Nw Electrodementioning

confidence: 99%

See 1 more Smart Citation

Electrodeposition of the MnO2 on the Ag/Au Core–Shell Nanowire and Its Application to the Flexible Supercapacitor

Seo

Kim

et al. 2021

Materials

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show abstract

“…Flexible electronic devices with prominent scalability and portability have been proposed for use in a wide array of wearable devices, electronic skins, smart textiles, and others [1,2]. The development of flexible electronic devices strictly relies on stretchable functional components and energy storage modules.…”

Section: Introductionmentioning

confidence: 99%

In situ deposited multilayer integrated hydrogels for deformable and stretchable supercapacitors

et al. 2021

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Hydrogel systems promote the development of flexible energy storage devices because of their inherent mechanical elasticity and ionic conductivity. However, achieving stable energy storage capacity under violent mechanical deformation is still a challenge for hydrogel devices. In this work, an all-in-one integrated supercapacitor (AISC) was assembled using in situ deposited polyaniline/graphene oxide nanocomposites for both sides of the incorporated ionic hydrogel electrolyte. The assembly process of the AISC was greatly simplified, and the displacement and separation of the multilayer structured hydrogel complex were avoided during mechanical deformation. The hydrogel electrolyte with ionic additives exhibited strong adhesion and flexibility, and high ionic conductivity, thereby ensuring the excellent specific capacitance and rate performance of the AISC. The specific capacitances of the AISC were 222.8 mF cm −2 at the current density of 0.2 mA cm −2 and 151.7 mF cm −2 at 3.2 mA cm −2 . The capacitance retention rate was 68.1%. The energy density of a piece of the device reached 44.6 µW h cm −2 at a power density of 120.0 µW cm −2 . Moreover, reliable and reproducible energy storage was acquired under bending, compression, and stretching deformations. The AISC was also easily assembled in series to power a light-emitting diode (LED) light. This work provides a facile approach to the construction of flexible supercapacitors for the development of energy storage devices in flexible electronics.

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“…In recent years, flexible, lightweight, and environmentally friendly electrodes for SCs have attracted increasing attention since they meet the needs for portable (e.g., foldable phones) and wearable (e.g., smart textiles) electronics [ 24 , 25 , 26 , 27 ]. In these devices, which exhibit high specific energy and power densities and long life cycles, all components, including the electrodes, are flexible.…”

Section: Introductionmentioning

confidence: 99%

Free-Standing, Flexible Nanofeatured Polymeric Films Prepared by Spin-Coating and Anodic Polymerization as Electrodes for Supercapacitors

et al. 2021

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Flexible and self-standing multilayered films made of nanoperforated poly(lactic acid) (PLA) layers separated by anodically polymerized poly(3,4-ethylenedioxythiophene) (PEDOT) conducting layers have been prepared and used as electrodes for supercapacitors. The influence of the external layer has been evaluated by comparing the charge storage capacity of four- and five-layered films in which the external layer is made of PEDOT (PLA/PEDOT/PLA/PEDOT) and nanoperforated PLA (PLA/PEDOT/PLA/PEDOT/PLA), respectively. In spite of the amount of conducting polymer is the same for both four- and five-layered films, they exhibit significant differences. The electrochemical response in terms of electroactivity, areal specific capacitance, stability, and coulombic efficiency was greater for the four-layered electrodes than for the five-layered ones. Furthermore, the response in terms of leakage current and self-discharge was significantly better for the former electrodes than for the latter ones.

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Flexible Transparent Supercapacitors: Materials and Devices

Cited by 166 publications

References 304 publications

Electrodeposition of the MnO2 on the Ag/Au Core–Shell Nanowire and Its Application to the Flexible Supercapacitor

Electrodeposition of the MnO2 on the Ag/Au Core–Shell Nanowire and Its Application to the Flexible Supercapacitor

In situ deposited multilayer integrated hydrogels for deformable and stretchable supercapacitors

Free-Standing, Flexible Nanofeatured Polymeric Films Prepared by Spin-Coating and Anodic Polymerization as Electrodes for Supercapacitors

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