Relationship between magnetization intensity and capacitor energy storage

Does magnetic field affect specific capacitance?

We find that the influence of magnetic field on the specific capacitance is remarkable in acidic and alkaline electrolytes but is negligible in neutral electrolytes. Furthermore, the direction and intensity of magnetic field, the concentration of electrolytes, and the voltammetry sweep affect the capacitance change.

Does magnetic field affect charge storage of carbon-based supercapacitors?

The capacitance change is related to scan rate and the electrolyte concentration Carbon-based supercapacitors (SCs) are important electrochemical energy storage devices and are often used in electronic equipment that generates a magnetic field. However, whether the magnetic field affects the charge storage of SCs is unknown.

Does the magnetic field affect the capacitance change in a non-magnetic aqueous SC system?

We have demonstrated a discovery for a non-magnetic aqueous SC system that the external magnetic field can induce significant but distinctly different capacitance changes in acidic and alkaline electrolytes, but not in neutral electrolytes. The direction of the magnetic field plays the important role in affecting the capacitance change.

Are magnetic device energy storage distribution relations constant?

According to the air gap dilution factor discussed in ampere-turns unchanged, magnetic induction intensity is constant, inductance constant several cases related to energy storage relationship, finally concluded that the magnetic device energy storage distribution relations.

Does magnetic field induced capacitance enhancement occur in alkaline and acidic electrolytes?

We have shown that magnetic field-induced capacitance enhancement is obvious in alkaline and acidic electrolytes. Because the concentration of electrolytes directly influences the mobility and transfer of ions, the investigation was focused on the different-concentration KOH and H 2 SO 4 electrolytes.

Does magnetic field affect charge storage of carbon-based electrolytes?

However, whether the magnetic field affects the charge storage of SCs is unknown. Here, we discover that applying an external magnetic field to carbon-based SCs can induce capacitance change in both aqueous acidic and alkaline electrolytes but not in neutral electrolytes.