Figures index

From

Review of Recent Advances of Supercapacitors Energy Storage Systems

A. T. Jee, Jehad H. Alsluimani, A. S. Alqurashi, A. A. Akkur, Ahmed M. Nahhas

Sustainable Energy. 2022, 10(1), 29-42 doi:10.12691/rse-10-1-3
  • Figure 1. Supercapacitors cell construction [3]
  • Figure 2. Schematic of a double layer ultracapacitor [6]
  • Figure 3. Schematic of a hybrid ultracapacitor [7]
  • Figure 4. Charger / discharge characteristics of double-layer and hybrid ultracapacitors [8]
  • Figure 5.1. Bidirectional Converter and equivalent circuit [10]
  • Figure 5.2. Variation of minimum stack capacitance and filter inductance [10]
  • Figure 6. BOOSTCAP BCAP0350 Supercapacitors from Maxwell
  • Figure 7. Power Flow from Wheel/Road Contact to the Energy Storage Elements [12]
  • Figure 8. Classification of Supercapacitors [12]
  • Figure 9. Technology drivers for supercapacitors [13]
  • Figure 10. Synthesis of rGO from graphene [15]
  • Figure 11. EDLCs models (a) Helmholtz model (b) Gouy-Chapman model (c) Stern model [16]
  • Figure 12. (a) Schematic and (b) SEM images illustration the preparation process and morphologies of TiN and Fe2N on GNS. (c) cycling performance and (d) Ragone plot of corresponding SC device. (e) Schematic representation of VOx NRs-Si NWs hierarchical structures used as SC electrode in LiCl electrolyte. (f) SEM cross-sectional view of as-synthesized VOx NRs-Si NWs hierarchical structures; insets indicating the dimensions of the NR branches. (g) Specific capacitances of different Vox NRs-Si electrodes compared to VOx film-Si NWs under various current densities. (h) The specific capacitance values of various VOx-Si electrodes along with the charge discharge process [17]