Revisited insights into charge storage mechanisms in electrochemical capacitors with Li2SO4-based electrolyte

“…Although the stability windows of both salts are bounded by H 2 and O 2 evolution reactions, they are much wider than the typical 1.2 V in acid or base electrolytes. The wide voltage window in neutral pH electrolytes has been largely attributed to the greater overpotential from the lacking of protons and hydroxyl ions or local pH change due to hydrogen adsorption at the negative electrode . However, the former may be more dominant in polymer electrolytes due to much slower movement of species within the polymeric structure.…”

Na₂SO₄‐Polyacrylamide Electrolytes and Enabled Solid‐State Electrochemical Capacitors

“…Although the stability windows of both salts are bounded by H 2 and O 2 evolution reactions, they are much wider than the typical 1.2 V in acid or base electrolytes. The wide voltage window in neutral pH electrolytes has been largely attributed to the greater overpotential from the lacking of protons and hydroxyl ions or local pH change due to hydrogen adsorption at the negative electrode . However, the former may be more dominant in polymer electrolytes due to much slower movement of species within the polymeric structure.…”

Na₂SO₄‐Polyacrylamide Electrolytes and Enabled Solid‐State Electrochemical Capacitors

“…The shi of the potential towards more negative values is caused by hydrogen sorption overpotential. 26,61,62 In the case of anodic polarization, the shi of the potential is marginal, and it is in the same range of values as in the case of the glassy carbon electrode. The situation is somewhat different in the case of microporous YP-80F carbon, where during cathodic polarization, the potential limitation is shied towards less negative values.…”

“…21 In some cases, it is possible to achieve a voltage of up to 1.8 V. [22][23][24] However, the latest research on "water-in-salt" electrolytes shows that even more than 2 V can be achieved for very concentrated electrolytes. 25,26 The third group of electrolytes is ionic liquids; their advantages include the possibility of reaching high voltages, up to 4 V; [27][28][29][30][31] non-ammability; and environmental friendliness. However, their high production cost and poor conductivity limit their application ability in high-power devices.…”

Peculiar role of the electrolyte viscosity in the electrochemical capacitor performance

“…For aqueous systems, the cathodic and anodic limits of the potential region where the electrolyte does not undergo electrochemical reactions are set by the hydrogen evolution (HER) and the oxygen evolution (OER) reactions, respectively, displaying a stability window of at least 1.23 V. This window can be enlarged by use of "water-insalt"-type electrolytes to achieve stability windows as large as 3 V [24,25]. However, the potential window suitable for determining double layer capacitance is shortened considerably by the presence of any species in the electrolyte that may undergo redox processes at the electrode/electrolyte interface [26], e.g. reduction of dissolved oxygen (ORR), or adsorption/desorption of ions in the solution as shown in Figure 2b.…”

Seven Steps to Reliable Cyclic Voltammetry Measurements for the Determination of Double Layer Capacitance