High‐energy‐density supercapacitors using supersonically sprayed water‐based precursors comprising cobalt iron oxide and reduced graphene oxide nanosheets

Kim, Taegun; Samuel, Edmund; Seol, Jaewoo; Lee, Hae‐Seok; Yoon, Sam S.

doi:10.1002/er.8143

Cited by 6 publications

(1 citation statement)

References 45 publications

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“…Supercapacitors are energy storage devices that are used in various fields of application such as healthcare devices, remote sensors, electric vehicles, and wearable electronics owing to their excellent power density, fast charging capability, and long lifetime [1][2][3]. The use of aqueous electrolytes in supercapacitors ensures their commercial viability and environmental safety [4]. The electrostatic charge accumulation of carbon materials and the capacitive Faradaic reaction of pseudocapacitive materials are the basic energy storage mechanisms of supercapacitors [5][6][7].…”

Section: Introductionmentioning

confidence: 99%

Bimetallic CoMoO4 Nanosheets on Freestanding Nanofiber as Wearable Supercapacitors with Long-Term Stability

Khadka

Samuel

Joshi

et al. 2023

International Journal of Energy Research

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Currently, lightweight wearable energy storage devices are in great demand owing to their use in wearable electronics and energy-efficient electric vehicles. Freestanding carbon nanofibers replace the need for metal substrates while providing a rapid electrical network owing to their excellent electrical properties. Bimetallic oxides with multivalent oxidation states facilitate the rapid transfer of electrolytic ions owing to efficient Faradaic reactions, thereby enhancing the overall energy storage capability. In this study, CoOx@CNF was derived from ZIF-67 (zeolitic-imidazolate framework) @PAN-2MI fibers that were stabilized in air at 280°C and then annealed in argon at 900°C. Subsequently, Co was seeded on the annealed CoOx@CNF and subjected to a hydrothermal process in sodium molybdate dihydrate solution to grow CoMoO4 nanosheets, eventually forming bimetallic CoMoO4@CNF. The concentration of sodium molybdate solution was varied to determine the optimal growth conditions for CoMoO4 nanosheets. The energy density of the optimal bimetallic CoMoO4@CNF sample was 166.5 μWh cm-2 at a power density of 200 μW cm-2; this represented a nearly twofold increase compared to that of the single metallic CoOx@CNF. Powering humidity sensors using only one CoMoO4@CNF supercapacitor was demonstrated. The optimal sample remained stable during long-term galvanostatic charge and discharge cycles ( N cyc = 30,000 ) and retained 100% of its specific capacitance.

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