Corpus ID: 56403464

Is the Schwarzschild Radius Truly a Radius

@article{Haug2016IsTS,
  title={Is the Schwarzschild Radius Truly a Radius},
  author={E. Haug},
  journal={viXra},
  year={2016}
}
This paper questions the assumption that the Schwarzschild radius actually represents a radius. It has recently been shown by Haug (2016) that the Schwarzschild radius for any object can simply be written as N2l_p, where N is the number of Planck masses into which we can ``hypothetically" pack an object of interest and l_p is the well known Planck length. The Schwarzschild radius seems to represent the length of the number of Planck mass objects we can ``hypothetically" pack a planet or star… Expand
Planets and Suns and Their Corresponding Sphere Packed Average Particles
When one talks about the density of a planet or star, one normally talks about the average density, despite the fact that the core is much more dense and the surface much less dense than the averageExpand
Newton’s and Einstein’s Gravity in a New Perspective for Planck Masses and Smaller Sized Objects
Here we derive Newton’s and Einstein’s gravitational results for any mass less than or equal to a Planck mass. All of the new formulas presented in this paper give the same numerical output as theExpand

References

SHOWING 1-10 OF 20 REFERENCES
Planck Quantization of Newton and Einstein Gravitation
In this paper we rewrite the gravitational constant based on its relationship with the Planck length and based on this, we rewrite the Planck mass in a slightly different form (that gives exactly theExpand
Kruskal Coordinates and Mass of Schwarzschild Black Holes: No Finite Mass Black Hole at All
When one presumes that the gravitational mass of a neutral massenpunkt is finite, the Schwarzschild coordinates appear to fail to describe the region within the event horizon (EH), of a SchwarzschildExpand
The Gravitational Constant and the Planck's Units: A Simplification of the Quantum Realm
In this paper, I suggest a new way to write the gravitational constant that makes all of the Planck units: Planck length, Planck time, Planck mass, and Planck energy more intuitive and simpler toExpand
The Theory of Radiation
IN his letter published in NATURE of October 9, Prof. Maclaren has referred to my use of the concept of a natural unit of angular momentum, and perhaps a few explanatory remarks may be useful, as theExpand
Fundamental constants: A cool way to measure big G
TLDR
A high-precision measurement of G is carried out using quantum interferometry with laser-cooled atoms, an experimental approach that differs radically from previous determinations, obtaining a value with a precision approaching that of the traditional measurements, and with prospects for considerable further improvement. Expand
To Have and Not to Have - the Paradox of Black Hole Mass
Cosmologists always claim that their black holes, mathematical fabrications entire as they are, have a finite mass. This mass, they say, is concentrated at their 'singularity', where volume is zero,Expand
Atom Interferometer Measurement of the Newtonian Constant of Gravity
TLDR
The Newtonian constant of gravity is measured using a gravity gradiometer based on atom interferometry using the differential acceleration of two samples of laser-cooled Cs atoms to investigate the change in gravitational field when a well-characterized Pb mass is displaced. Expand
Gauge invariance and the structure of charged particles
SummaryThe Weyl principle of gauge invariance is used to obtain an enlarged gauge invariant curvature tensor consisting of the usual Einstein-Ricci tensor plus terms involving the electromagneticExpand
Interview - Proof That the Black Hole Has No Basis in General Relativity or Newtonian Gravitation and Therefore Does Not Exist
This document is the transcript of an interview of me conducted by American scientists who requested me to explain in as simple terms as possible why the black hole does not exist. I provide fiveExpand
Precision measurement of the Newtonian gravitational constant using cold atoms
TLDR
The precise determination of G is reported using laser-cooled atoms and quantum interferometry to identify the systematic errors that have proved elusive in previous experiments, thus improving the confidence in the value of G. Expand
...
1
2
...