The electrons of the graphite electrode are excited by HGS1, generating another high-frequency level coupling current. Just like the induced current, when it touches aluminum, it will contact electrons to generate current, which will generate electrostatic attraction.
First, the electrical characteristics of resin electrodes are not established at all. It is thought that the gel electrodes reduce the electric field strength, possibly resulting in a reduced field strength that cannot stop the movement of electrons. Experiments have shown that the hollow resin electrode can effectively prevent the movement of electrons, rather than reduce the electric field strength. However, it would be too one-sided to think that hollow resin electrodes are bad because of this. I once engaged in related research at a highly respected university in the UK. The original text is as follows: As some people say, current electronics teachers teach "electric potential". It is harmful to take classes without even knowing the basic structure of motion. Not shallow.
Electricity is geometric physics, and every part can never be "shrunk". Are electrodes getting smaller and smaller causing problems? For some industrial products, people will use the small-size electrode design to make electrodes as much as possible. The smaller the electrode size, the easier it is to work stably and safely in different application limit voltage and current ranges. From this point of view, the hollow resin electrode is designed to solve the electronic engineering problems of various electrode products. To make the electrode "as small as possible", it is necessary to mix the electrode material with special nanomaterials such as nanoparticles at the nanoscale. construction.
Of course, a "polar plate" is more than one "polar plate". Many nano-electrode materials are efficient and suitable for industrial environments with n plates, such as bio-level acrylic and activated carbon materials (such as benzene series). Others such as multi-layer polyethylene board, high-strength sbs, and some composite materials of super PTFE polyethylene. These materials are more resistant to high temperatures than polymers and can be used not only as electrode materials but also as insulators. These materials achieve low electrical conductivity and are suitable for a variety of applications.