Volume 3, Issue 2, March 2015, Page: 12-16

On a Casimir-Dark Energy Nano Reactor

Mohamed S. El Naschie, Dept. of Physics, University of Alexandria, Alexandria, Egypt

Received: Feb. 12, 2015;
Accepted: Feb. 27, 2015;
Published: Mar. 3, 2015

DOI: 10.11648/j.nano.20150302.11 View 3281 Downloads 318

Abstract

The paper is a general outline of the theoretical principle and basic design concepts of a proposed Casimir dark energy nano reactor. In a nutshell the theory and consequently the actual design depends crucially upon the equivalence between the dark energy density of the cosmos and the faint local Casimir effect produced by two sides boundary condition quantum waves. This Casimir effect is then colossally amplified as a one sided quantum wave pushing from the inside against the Möbius-like boundary with nothing balancing it from the non-existent outside. In view of our theory, this is essentially what led to the observed accelerated expansion of the cosmos. As in any reactor, the basic principle in the present design is to produce a gradient so that the excess energy on one side flows to the other side. Thus in principle we will restructure the local topology of space using material nanoscience technology to create an artificial local high dimensionality with a Dvoretzky theorem like volume measure concentration. Without going into the intricate nonlinear dynamics and technological detail, it is fair to say that this would be pure, clean, free energy obtained directly from the topology of spacetime. Needless to say the entire design is based completely on the theory of quantum wave dark energy proposed by the present author for the first time in 2011 in a conference held in the Bibliotheca Alexandrina, Egypt and a little later in Shanghai, Republic of China.

Keywords

Casimir Effect, Dark Energy, E-Infinity, Cantorian Spacetime, Nano Reactor, Free Energy, Möbius Boundary

To cite this article

Mohamed S. El Naschie,
On a Casimir-Dark Energy Nano Reactor,

*American Journal of Nano Research and Applications*. Vol. 3, No. 2, 2015, pp. 12-16. doi: 10.11648/j.nano.20150302.11Reference

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