THE THEORY OF MOTION OF QUANTUM ELECTROMECHANICAL PLASMOID NANOBOTS IN A CONDENSED-STATE MEDIUM

摘要

The theory of motion of quantum electromechanical plasmoid nanobots in a condensed-state medium is presented. The mechanism of a nanobot functioning is shown to be related to the quantum exchange between a nanoparticle and the quantum-field condensed-state system realized by a tangled (e~–e~+)-plasmoid pair. The operation of an (e~–e~+)-plasmoid is interpreted as a quantum analog of a fuel cell based on the nanoelectromechanical systems (NEMS) of a nanobot. It is the electrical and magnetic fields of force of the (e– e+)-plasmoid which control the quantum motion of the NEMS-based nanobot. This ensures its response to an external action and allows the respective physical tools to be designed in order to control self-motion of the NEMS-based nanobot in a material medium. Two available mechanisms of the relaxational self-motion of a nanobot in the condensed matter are shown: conversion of the internal quantum-mechanical energy of the nanobot into the electrical energy of a quantum (e~–e~+)-plasmoid and conversion of the electrical energy of a quantum (e~–e~+)-plasmoid into the mechanical energy of the nanobot’s motion in a material. These mechanisms prescribe a discrete manipulation of the NEMS-based nanobot in a material medium. The time, displacement, forces and power involved in the NEMS-based nanobot transportation are estimated.