SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W4366757033> ?p ?o ?g. }

Showing items 1 to 100 of ±170 with 100 items per page.

W4366757033 endingPage "36" @default.
W4366757033 startingPage "1" @default.
W4366757033 abstract "AbstractContinuous technical advancements in a variety of industries, such as portable electronics, transportation, green energy, are frequently hampered by the inadequacy of energy-storage technologies. Asymmetric supercapacitors can expand their operating voltage window past the thermodynamic breakdown voltage of electrolytes by utilizing two distinct electrode materials, providing a workaround for the symmetric supercapacitors’ energy storage constraints. This evaluation offers a thorough understanding of this area. To comprehend the extensive research done in this field, we first examine the fundamental energy-storage mechanisms and performance evaluation standards for asymmetric supercapacitors. The most recent developments in the design and manufacture of electrode materials as well as the general structure of asymmetric supercapacitors. We have also discussed a number of significant scientific issues and offer our opinions on how to improve the electrochemical properties of future asymmetric energy storage devices. First, methods for designing high-performance electrode materials for supercapacitors must be developed; next, controllably built supercapacitor types must be attained (such as symmetric capacitors including double-layer and pseudocapacitors, asymmetric capacitors, and Li-ion capacitors). This review is timely because of the rapid expansion of research in this area. It summarizes recent developments in the study and creation of high-performance electrode materials with high supercapacitors. A number of crucial topics for enhancing the energy density of supercapacitors are examined, along with some reciprocal correlations between the main impacting parameters. Difficulties and prospects in this fascinating field are also covered. This offers a fundamental understanding of supercapacitors and serves as a crucial design rule for enhanced next-generation supercapacitors that will be used in both industrial and consumer applications. In this context, we extensively reviewed the classification of supercapacitor, EDLC (activated carbon, carbon aerogel, carbon nanotube), Pseudocapacitors, conducting polymers, metal oxides, hybrid materials, composite hybrids, rechargeable batteries, asymmetric devices and its design, aqueous solid state, fiber based asymmetric device, graphene based asymmetric device, terminologies used during the electrode selection, positive and negative electrodes in asymmetric device, material used for fabrication of negative electrodes, electrochemical performance of various devices which are fabricated by different electrode materials. Performance of material for various asymmetric device applications, conclusions outlook, recent developments in asymmetric devices. The current review may offer a thorough understanding and future prospects for developing negative electrodes to enhance asymmetric supercapacitor performance.Keywords: Asymmetric supercapacitornegative electrodesnanoparticlesspecific capacitancecharging-discharging AcknowledgmentsOne of the authors, Vandana M, would like to thank the Centre for Research, CHRIST (Deemed to be University), for providing the post-doctoral fellowship.Disclosure statementNo potential conflict of interest was reported by the authors." @default.
W4366757033 created "2023-04-24" @default.
W4366757033 creator A5016321580 @default.
W4366757033 creator A5051562601 @default.
W4366757033 creator A5057490598 @default.
W4366757033 creator A5067916312 @default.
W4366757033 date "2023-04-22" @default.
W4366757033 modified "2023-10-04" @default.
W4366757033 title "Recent advances in the development, design and mechanism of negative electrodes for asymmetric supercapacitor applications" @default.
W4366757033 cites W1970675709 @default.
W4366757033 cites W1979189818 @default.
W4366757033 cites W1983759473 @default.
W4366757033 cites W1993243068 @default.
W4366757033 cites W2020732878 @default.
W4366757033 cites W2022097579 @default.
W4366757033 cites W2024661936 @default.
W4366757033 cites W2038702334 @default.
W4366757033 cites W2041751986 @default.
W4366757033 cites W2044347440 @default.
W4366757033 cites W2050571756 @default.
W4366757033 cites W2050819310 @default.
W4366757033 cites W2053328406 @default.
W4366757033 cites W2053526231 @default.
W4366757033 cites W2054273141 @default.
W4366757033 cites W2054806846 @default.
W4366757033 cites W2057861719 @default.
W4366757033 cites W2064885855 @default.
W4366757033 cites W2074262287 @default.
W4366757033 cites W2096683902 @default.
W4366757033 cites W2127177421 @default.
W4366757033 cites W2297513100 @default.
W4366757033 cites W2301134156 @default.
W4366757033 cites W2329246126 @default.
W4366757033 cites W2400292030 @default.
W4366757033 cites W2506871477 @default.
W4366757033 cites W2536358365 @default.
W4366757033 cites W2574394697 @default.
W4366757033 cites W2591468107 @default.
W4366757033 cites W2591881098 @default.
W4366757033 cites W2619569651 @default.
W4366757033 cites W2625287896 @default.
W4366757033 cites W2748717829 @default.
W4366757033 cites W2766365724 @default.
W4366757033 cites W2784233427 @default.
W4366757033 cites W2793212697 @default.
W4366757033 cites W2811244012 @default.
W4366757033 cites W2896566614 @default.
W4366757033 cites W2901870033 @default.
W4366757033 cites W2912164404 @default.
W4366757033 cites W2913659563 @default.
W4366757033 cites W2936469780 @default.
W4366757033 cites W2942579201 @default.
W4366757033 cites W2948937499 @default.
W4366757033 cites W2963373607 @default.
W4366757033 cites W2969694845 @default.
W4366757033 cites W2971235927 @default.
W4366757033 cites W2972731316 @default.
W4366757033 cites W2979681494 @default.
W4366757033 cites W2981271378 @default.
W4366757033 cites W2981839917 @default.
W4366757033 cites W2986383993 @default.
W4366757033 cites W2996147483 @default.
W4366757033 cites W2997608590 @default.
W4366757033 cites W2997785232 @default.
W4366757033 cites W2998073847 @default.
W4366757033 cites W3000611433 @default.
W4366757033 cites W3018726926 @default.
W4366757033 cites W3020553326 @default.
W4366757033 cites W3027283759 @default.
W4366757033 cites W3035289667 @default.
W4366757033 cites W3041219794 @default.
W4366757033 cites W3044478710 @default.
W4366757033 cites W3045725287 @default.
W4366757033 cites W3045819541 @default.
W4366757033 cites W3046625557 @default.
W4366757033 cites W3081584472 @default.
W4366757033 cites W3083839986 @default.
W4366757033 cites W3085240760 @default.
W4366757033 cites W3108580534 @default.
W4366757033 cites W3112853087 @default.
W4366757033 cites W3120473317 @default.
W4366757033 cites W3140219000 @default.
W4366757033 cites W3148073666 @default.
W4366757033 cites W3157417758 @default.
W4366757033 cites W3163426912 @default.
W4366757033 cites W3194233216 @default.
W4366757033 cites W3197050884 @default.
W4366757033 cites W3197902240 @default.
W4366757033 cites W3200190643 @default.
W4366757033 cites W3200714359 @default.
W4366757033 cites W3201518190 @default.
W4366757033 cites W3204554236 @default.
W4366757033 cites W3205022728 @default.
W4366757033 cites W3206658969 @default.
W4366757033 cites W3216828878 @default.
W4366757033 cites W4200497253 @default.
W4366757033 cites W4205296839 @default.
W4366757033 cites W4205414461 @default.