Electrical and Electronic Devices, Circuits, and Materials. Группа авторов

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Wh/kg, 6.68 mWh cm^-3 [49] pACM/Et4NBF₄-AN 6.2 F cm^-3(124.7mF cm^-2;72.1 F/g) at 0.5 mAcm^-2 88.7 % (after 10000 cy.) 6.18mWh cm^-3 (123.5 mWh cm^-2; 71.4Wh/kg) 0.033Wc^-3 (0.668 mWcm^-2; 0.386 kWkg^-1 [50] PEGBEM-g-PAEMA 1.23 × 10^-3S/cm 55.5 F/g at 1.0 A/g - 25 Wh/kg 900 kW/kg [52] chitosan (CS), starch, glycerol, LiClO₄ 3.7 × 10^-4 S/cm 133(10 mV/s) - 50 Wh/kg 8000 W/kg [53] pDADMATFSI 5 × 10^-4 S/cm (25 oC) 3 × 10^-3 S/cm (60 °C) 100 F/g (1mA cm²) ^— 32 Wh/kg (20 °C) 42 Wh/ kg(60 °C) - [54] PVA-H₂SO₄-HQ 29.3 mS/cm 491.3 F/g (0.5 A/g) 82.9 % 18.7 Wh/kg 245 W/kg [55] PVA-H₂SO₄-MB 29.6 mS/cm 563.7 F/g (0.5 A/g) 81.8 % - - (PVA)/CH₃COONH₄/BmImCl 7.31 mS/cm 27.76 F/g - 2.39 Wh/kg 19.79 W/kg [56] PMMA - C₄BO₈Li or LiBOB -EC/PC 3.27 S/cm m (298 K) 7.46 mS/cm (303 K) 685 mF g^-1 - - - [57] PVdF-HFP- Mg(CF₃SO₃)₂ 2.16 × 10^-4 S/cm 106 F/g - 23 Wh/kg - [58] PVA/BmImCl, BmImBr, BmImI (5.74 ± 0.01) mS/cm (BmImCl) 19.42 F/g - 1.77 Wh/kg 37.83 kW/kg [59] (9.29 ± 0.01) mS/cm (BmImBr) 21.82 F/g - 2.19 Wh/kg 41.27 kW/kg (9.63 ± 0.01) mS/cm (BmImI). 52.78 F/g - 6.92 Wh/kg 50.25 kW/kg PILTFSI/PYR₁₄TFSI (IL-b-PE1) 0.5 mS/cm 110 F/g - 35 Wh/kg 250 W/kg [60] PILTFSI/PYR₁₄FSI (IL-b-PE2) 2.1 mS/cm 150 F/g - 36 Wh/kg 230 W/kg PVDF-HFP/EMimTFSI ϸ LiTFS 4.5 mS/cm 108 F/g - 15 Wh/kg 213 W/kg [61] (poly(VA-co-AN))-1-ethyl-3-methylimidazolium (IL)/LiBF4 2 × 10^-4 S/cm at RT and 7 × 10^-3 S/cm at 100 °C 80 F/g(1 A/g) 99 % (after 1000 cy) 61 Wh/kg 500 W/kg [62] PVA-H₂SO₄-P-benzenediol - 474.29 F/g 91 % (after 3000 cy) 11.31 Wh/kg - [63]

      Table 3.5 Reported polymer electrolytes and fabricated supercapacitor performance.

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Patent application number	Year	Invention
US6356432B1 United States	2002	Supercapacitor having a non-aqueous electrolyte and two carbon electrodes each containing a binder and an electrochemically active material constituted by active carbon having a Specific Surface area greater than about 2000 m/g.
1263/MUM/2004 A	2006	Polyaniline thin films synthesized by electrochemical anodization at constant potentials. The electrochemical capacitor was formed with H2SO4 solution. The specific supercapacitance of 650 F/g and interfacial capacitance of 0.14F/cm2 were obtained.
US20070076349A1 United States	2007	Supercapacitors having organosilicon electrolytes, high surface area/porous electrodes, and optionally organosilicon separators.
US7226702B2 United States	2007	Solid electrolyte made of an interpenetrating network type solid polymer comprised of two compatible phases: a crosslinked polymer for mechanical strength and chemical stability, and an ionic conducting phase.
US20100259866A1 United States	2010	Fabrication of a supercapacitor by constructing a mat of conducting fibers, binding the mat with an electrolytic resin, and forming a laminate of the electrodes spaced by an insulating spacer.