We have the following impact of the neutral zone magnetic field of a permanent magnet- electric current is generated in the conducting loop moving in the neutral zone magnetic field.
Directed motion. One of the properties of the neutral zone magnetic field of a permanent magnet is a directional movement force (magnetic self-motion) along with strong attraction to any main pole of the other magnet (a ferromagnet magnetized with a main pole of a permanent magnet). Having serial connection of the opposite poles, we create two-directional motion line. Electric current occurrence. We have the following impact of the neutral zone magnetic field of a permanent magnet- electric current is generated in the conducting loop moving in the neutral zone magnetic field. We insert a sharp iron core in the center of a copper wire coil. If we touch the steel core with a center of a flat edge with a neutral zone of magnetic cube with axial magnetization, and start reciprocating movements (avoiding the air gap between the core and the magnet) along the lines of the magnet force for 1/10 of the surface with the neutral zone, we generate oppositely directed electric current. We insert a sharp iron core in the center of a copper wire coil. Then we start liner movement (keeping the certain air gap) with a flat edge with a neutral zone of magnetic cube with axial magnetization perpendicular to the iron core. The movement is parallel to inner magnet force lines. We shall draw the magnet cube toward and back (let us compare the situation with current generation with iron conductivity). So we have end movement to and back of the opposite poles (ebb and flow magnetic field) - one direction currents, approx. for 30%. The flat edge with a neutral zone has 100% backward direction current. The same activities without the iron core – we see the same picture of the magnetic field properties. Electric current generation. Comparison of the results can be done in the following way. We can locate a circular electric-driven rotating platform next to the copper coil and compare the current between the main pole of the permanent magnet (electromagnetic induction) and the flat edge with a neutral zone (magnetic self-motion) and installing the magnetic cube on the platform with the certain air gap between the magnet and the iron core of the copper coil. Having the same intensity of the impact, we generate approximately equal currents.

The structure formation of magnesium hydroxide in a magnetic field of varying intensity depending on the concentration of salt solution and the conditions for its deposition and heat treatment has been studied. It has been shown that the magnetic field increases the sorption capacity of samples and reduces their surface area, and that method of fast hydroxide deposition usually generates more uniporous structure of the sample. The explanation has been proposed for observed changes in structural parameters of synthesized samples.