By employing a combination of magnetic forces and those from electrostatic fields, a new stabilizer is able, unlike those employing dynamic effects, to function at any speed with no need for sensors or dynamically generated electrical currents. Embodiments are provided that stabilize the radial, axial and tilt instability. In addition to its use for stabilization, the radial stabilizer described herein also functions as an eccentricity detector.

The result of the characteristics associated with the magnetic and electro-static waves being generated from all naturally occurring refined magnets enabled the design of the Repulsive Magnetic Motor and Generator. The Repulsive Magnetic Motor and Generator is designed to take advantage of the different fields of a natural magnet's repulsion and power generation. The simplified design allows the same repulsive magnetic arm rotation found in the Repulsive Magnetic Motor to drive the magnets rotating through magnetic pick-up wire coils creating AC power in the Generator. Through external circuit design the AC power generated is offered in an AC or DC format. The Repulsive Magnetic Motor and Generator is designed to operate as a test device and as a production device due to the flexibility of the design.

The use of repulsive magnetic and electro-static fields as the driving force in the powering of other designs could widened the options available with wind, solar, nuclear, aquatic, oil, coal, wood and even steam power. The theory has presented a new and different way to view older understood actions in science, enabling a better understanding of why the resultant is the way it is and allowing a wider view of actions one could explore.

A friction preventing apparatus and a method of manufacturing the same are provided. The apparatus includes: a first object; a second object spaced apart from the first object and facing the first object; and a plurality of charged nanoparticles provided on a surface of one of the first and second objects, such that the nanoparticles are disposed between the first object and the second object. A potential difference is formed between the first and second objects. The nanoparticles may be positively charged and may adhere to the first object, and the first object has a potential lower than a potential of the second object. The nanoparticles may be negatively charged and may adhere to the second object, and the second object has a potential higher than a potential of the first object.