2015
DOI: 10.1002/adma.201503333
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High‐Performance Pseudocapacitive Microsupercapacitors from Laser‐Induced Graphene

Abstract: All-solid-state, flexible, symmetric, and asymmetric microsupercapacitors are fabricated by a simple method in a scalable fashion from laser-induced graphene on commercial polyimide films, followed by electrodeposition of pseudocapacitive materials on the interdigitated in-plane architectures. These microsupercapacitors demonstrate comparable energy density to commercial lithium thin-film batteries, yet exhibit more than two orders of magnitude higher power density with good mechanical flexibility.

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Cited by 491 publications
(392 citation statements)
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“…4e), which was comparable to our aqueous device (76% after 10000 cycles, Fig. S10c) and state-of-the-art reported PHMSs and other asymmetric MSs, e.g., CNT//MnO 2 /CNT (74.7% after 10000 cycles), 32 graphene-FeOOH//graphene-MnO 2 (84% after 2000 cycles), 12 graphene quantum dots//MnO 2 (80% after 3000 cycles), 46 graphene quantum dots//polyaniline (85% after 1500 cycles), 45 and most reported sandwich ASCs, such as VN//Co(OH) 2 (86% after 4000 cycles), 15 Co(OH) 2 /graphene foam//graphene/ Fe 3 O 4 @carbon (72% after 8000 cycles), 47 and VN/NiOx (85% after 1000 cycles). 48 In addition, our mask-assisted manufacturing strategy is highly flexible for fabricating miniaturized VN//Co (OH) 2 -PHMSs with tailored device size and geometries (Fig.…”
Section: Nanoflowerssupporting
confidence: 88%
See 1 more Smart Citation
“…4e), which was comparable to our aqueous device (76% after 10000 cycles, Fig. S10c) and state-of-the-art reported PHMSs and other asymmetric MSs, e.g., CNT//MnO 2 /CNT (74.7% after 10000 cycles), 32 graphene-FeOOH//graphene-MnO 2 (84% after 2000 cycles), 12 graphene quantum dots//MnO 2 (80% after 3000 cycles), 46 graphene quantum dots//polyaniline (85% after 1500 cycles), 45 and most reported sandwich ASCs, such as VN//Co(OH) 2 (86% after 4000 cycles), 15 Co(OH) 2 /graphene foam//graphene/ Fe 3 O 4 @carbon (72% after 8000 cycles), 47 and VN/NiOx (85% after 1000 cycles). 48 In addition, our mask-assisted manufacturing strategy is highly flexible for fabricating miniaturized VN//Co (OH) 2 -PHMSs with tailored device size and geometries (Fig.…”
Section: Nanoflowerssupporting
confidence: 88%
“…So far, several strategies to manufacture the planar microelectrodes for MSs based on two different electrodes have been developed by micro-electro-mechanical systems (MEMS) fabrication, 27 inkjet printing, [28][29][30] electrochemical deposition 28,31,32 and combined with laser-irradiation assisted method. 12,33 The MEMS microfabrication, combining photolithography and a wet or dry etching process, is a well-established technique for processing high-resolution micropatterns. 27,34 However, this technique usually involves multiple separated steps, such as spin-coating of photoresist, masked irradiation, development, plasma etching, or magnetron sputtering, 27,35 resulting in low efficiency of device assembly in a large scale.…”
Section: Introductionmentioning
confidence: 99%
“…Recently, an inexpensive laser-inducing technique at room temperature has been applied to prepare graphene on polyimide (PI) substrate, and the resulting laser-induced graphene (LIG) has been demonstrated to be a ready electrode material for supercapacitors due to its 3D porous multilayer structure. [30][31][32] This work introduces 3D LIG directly from polyimide to prepare all-solid-state, highly stretchable, and transparent MSCs, using as the active material on silicone rubber substrates. The 3D network of LIG with interdigital microelectrode structure is obtained by using laser-inducing method on PI substrate.…”
Section: Doi: 101002/smll201702249mentioning
confidence: 99%
“…[1] On the other hand, the microfabrication technology opens up the possibilities for fabrication of microenergy-storage-devices with planar interdigitated structure. [20][21][22][23][24][25] Conductive polymers after being doped, advantageous to other pseudocapacitive materials (metal oxides), [26,27] offer low cost, high conductivity, lightweight, and excellent flexibility. Although these μSCs show excellent energy-storage performance (e.g., excellent power density and long cycle life) and great feasibility to be integrated to miniaturized devices, the usage scenarios are still limited due to the following disadvantages.…”
mentioning
confidence: 99%