SCANNING PROBE OF A NUCLEAR-POWER MICROSCOPE WITH A DIVIDED NUCLEAR-CONTROLLED NUCLEAR-ELECTROMAGNETIC CONTROL ELEMENT ON THE BASIS OF QUANTUM POINTS AND MAGNETIC NANOPARTICLES OF THE NUCLEAR-SHELL STRUCTURE

摘要

The utility model refers to the measuring technique and can be used in atomic force microscopy to diagnose nanoscale structures. The scanning probe contains a cantilever connected to a probing needle that is threaded and rigidly fixed in one of the through nanopores of a polymer sphere of larger diameter with quantum dots of the core-shell structure, and the tip of the probing needle emerging from the larger diameter polymer sphere is movably connected by two nested carbon nanotubes with a detachable and autonomously functioning small diameter polymeric sphere with through nanopores filled with quantum dots and magnetic nanoparticles with the same orientation polarity of the core-shell structure. The components of the scanning probe are magnetically transparent and opto-magnetocrystalline. Remote control of the excitation of quantum dots of the core-shell structure and their autonomous movement along the Z coordinate during scanning of the side walls of the nanodetects of the diagnostic object is carried out by means of two external counter-directed synchronized electromagnetic fields. The technical result is the possibility of scanning nanowarets along the Z coordinate, the depth of which is longer than the length of the probing needle, while simultaneously combining combinations of point thermal and electromagnetic with the optical wavelength of the impact on the walls of the nanoclusters, while simultaneously measuring the mechanical characteristics (the UNGA module) of this stimulating effect at one point the surface of the diagnostic object with the coordinates X, Y, without affecting the neighboring sections. 3 ill.