Quantum Gravity and String Theory

0703 Submissions

[2] viXra:0703.0018 [pdf] submitted on 18 Mar 2007

The Theory of Cold Quantum (Counter Gravitation Theory)

Authors: Cao junfeng, Cao Rui
Comments: recovered from sciprint.org

In many years study, I've discovered most important force in the nature, that is cold quantum, under the pressure of cold to hot, the material is formed, it has the gravity under the cold quantum pressure , then the celestial body begins to move, cold quantum pressure exists in the space, exists in the material, it's the cold quantum pressure that makes the formation of four seasons in the earth, the whirlpool produced from the cold quantum pressure pushes moving of celestial body, push produces turn and change, cold freezes the water to ice, there is no other force can do this .People knew the strong strength of cold quantum, therefore, I said the cold quantum pressure is the biggest force ever exist in the nature , but there are some people don't recognize the exist of strong cold quantum, after you have seen this article, please study it carefully , try to analyze whether I'm right or wrong , if I'm wrong , please criticize me , if I'm right , please help and support me. Here I'll express many thanks, at the same time, I'd like to thank all the people who has helped or supported me.
Category: Quantum Gravity and String Theory

[1] viXra:0703.0017 [pdf] submitted on 10 Mar 2007

Gravitational Schr�dinger Equation from Ginzburg-Landau Equation, and Its Noncommutative Spacetime Coordinate Representation

Authors: V. Christianto
Comments: recovered from sciprint.org

Despite known analogy between condensed matter physics and various cosmological phenomena, a neat linkage between low-energy superfluid and celestial quantization is not yet widely accepted in literature. In the present article we argue that gravitational Schr�dinger equation could be derived from time-dependent Ginzburg-Landau (or Gross-Pitaevskii) that is commonly used to describe superfluid dynamics. The solution for celestial quantization takes the same form with Nottale equation. Provided this proposed solution corresponds to the facts, and then it could be used as alternative solution to predict celestial orbits from quantized superfluid vortice dynamics. Furthermore, we also discuss a representation of the wavefunction solution using noncommutative spacetime coordinate. Some implications of this solution were discussed particularly in the context of offering a plausible explanation of the physical origin of quantization of motion of celestial objects.
Category: Quantum Gravity and String Theory