One percent of the oxygen mobility of the graphite electrode is three times the working voltage, and three times the working voltage means three times the discharge current, which is five times the current. The discharge current of graphite electrodes also includes the effect of temperature rise on graphite deformation and the energy deintercalated during graphite movement. The density and conductivity of the carbon layer have nothing to do with the graphite quality but are related to the working voltage and the user's current and voltage. The difficulty in the preparation of graphite electrodes lies in the poor combination of atoms and ligands on carbon. The atomic force and the compactness of the chemical bond lead to the poor release of protons at the working end of graphite, and the poor release of protons from graphite leads to the higher energy of graphite. At the same time, a large number of excitations of many atomic masses can lead to a significant energy loss, resulting in fabrication defects.

There are two main preparation methods for graphite on integrated circuits, 1 is the usual method of producing graphite electrodes, and 2 is graphene, which is now very mature. Graphite comprises carbon or metal elements with high chemical bonds, while graphene uses graphite as the base carbon. Graphite and graphene are widely used. Graphene is used as an electrode, which can be used in superconductors, photoconductors, high-power electronic devices, etc. Using graphene as an electrode can also be used in low-frequency circuits, and wireless communication of UHF and low-frequency signals.

But do you know why the variation of graphite compound in the graphene module compound, leads to the variation in properties? Because the uneven gravitational force between carbon atoms in graphite has a very strong resistance to their combination, it will cause different elements to be deposited in graphene, resulting in certain Changes in the area of the component resulting in a change in performance.