Forcing or Forced Exertions in Amalgamation of Nanoparticles and Particles inside the Solution

21 July 2020, Version 6
This content is a preprint and has not undergone peer review at the time of posting.

Abstract

The study of forcing or forced exertions in amalgamating or amalgamated nanoparticles and particles inside the solution is important for the scientific societies in the fields of physical, chemical and mathematical sciences. Observing live dynamics of nanoparticles and particles inside the solution is a challenging task. Again, it is not an appropriate way to discuss amalgamating nanoparticles and particles based only on visualized dynamics. However, suitably captured microscopic images can identify different modes of forcing or forced exertions in amalgamated nanoparticles and particles. Nanoparticles and particles when just at resting positions amalgamate under resultant differences of exerting forces, which are not only related to poles of occupied quadrants, but also related to their own drawn poles. So, colloidal nanoparticles and particles amalgamate from sides experiencing a greater exertion of force. In amalgamation of nanoparticles and particles, the exerted force successively remains in mute, alert and functioning mode. Contrarily, the energy behavior successively remains in functioning, alert and mute mode. Amalgamation of nanoparticles and particles depends on their features and conceived focusing lengths. This is through the resultant differences of exerting forces for two frame of references. Particles of geometrical shapes largely experience the even exertion of forces in their amalgamation, which is not the case for distorted particles. Nanoparticles and particles inside the solution are the best candidates to track nature of exerting forces, and so is the case with energy behaviors, too.

Keywords

Nanoparticles
Particles
Forced exertion
Agglomeration
Forcing exertion
Amalgamation
Focusing length
Suspected point

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