About the quantum-mechanical nature of wear on magnetized cutting and deforming tools

In this article, we present a hypothesis about the nature of anti-adhesion as a method of processing cutting and deforming tools by the magnetic field. This hypothesis is based on analysis of operating experience and experimental studies on a wide range of instruments. We propose to study the influence of magnetic fields on the adhesion process using an atomic-electron approach based on examination of the processes taking place at the level of the crystal lattice of the nanostructure's magnetized body. Theoretical modeling shows that the influence of the magnetic field on the process of adhesion may be due to a change in the energy state of nanostructures in the crystal lattice in accordance with the quantum-mechanical nature of their response to magnetic effects. Specific attention is paid to the methodological aspects of experimental modeling. New results were reached that illuminate the effect of wear on the prevailing conditions of adhesive wear on the magnetization instruments. A new mechanism of influence is proposed by processing the magnetic field on the wear, from which it is concluded that the appearance of an electron system with a modified energy level that is resistant to the formation of strong chemical bonds caused the adhesion.