Difference between revisions of "An Electrostatic Solution for the Gravity Force and the Value of G"
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| − | ''Written in 1999, published posthumously.'' This paper claims that gravity is electrostatic, and substantiates this claim by deriving, through basic electrostatic relationships, a simple equation for gravity forces that includes an expression for the gravity constant G in terms of electrostatic parameters. Applied to interaction between two separated sub-atomic particles in open space, the derivation of G results in a value that falls within the range of the currently best known and accepted empirical measurements. The general electrostatic gravity equation next derived is applicable for all physical entities, however small, or large, thus presenting a comprehensive new way of perceiving and understanding gravity forces. A variety of other important conclusions also follow. For example, the electrostatic approach helps to explain why, regardless of the precision of their measurements, experimenters who use different physical layouts may continue to find different empirical values for G. | + | ''Written in 1999, published posthumously.'' This paper claims that gravity is electrostatic, and substantiates this claim by deriving, through basic electrostatic relationships, a simple equation for gravity forces that includes an expression for the gravity constant G in terms of electrostatic parameters. Applied to interaction between two separated sub-atomic particles in open space, the derivation of G results in a value that falls within the range of the currently best known and accepted empirical measurements. The general electrostatic gravity equation next derived is applicable for all physical entities, however small, or large, thus presenting a comprehensive new way of perceiving and understanding gravity forces. A variety of other important conclusions also follow. For example, the electrostatic approach helps to explain why, regardless of the precision of their measurements, experimenters who use different physical layouts may continue to find different empirical values for G. |
| − | [[Category:Gravity]] | + | [[Category:Scientific Paper|electrostatic solution gravity force value g]] |
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| + | [[Category:Gravity|electrostatic solution gravity force value g]] | ||
Latest revision as of 19:17, 1 January 2017
| Scientific Paper | |
|---|---|
| Title | An Electrostatic Solution for the Gravity Force and the Value of G |
| Read in full | Link to paper |
| Author(s) | Morton F Spears |
| Keywords | {{{keywords}}} |
| Published | 2010 |
| Journal | Galilean Electrodynamics |
| Volume | 21 |
| Number | 2 |
| No. of pages | 10 |
| Pages | 23-32 |
Read the full paper here
Abstract
Written in 1999, published posthumously. This paper claims that gravity is electrostatic, and substantiates this claim by deriving, through basic electrostatic relationships, a simple equation for gravity forces that includes an expression for the gravity constant G in terms of electrostatic parameters. Applied to interaction between two separated sub-atomic particles in open space, the derivation of G results in a value that falls within the range of the currently best known and accepted empirical measurements. The general electrostatic gravity equation next derived is applicable for all physical entities, however small, or large, thus presenting a comprehensive new way of perceiving and understanding gravity forces. A variety of other important conclusions also follow. For example, the electrostatic approach helps to explain why, regardless of the precision of their measurements, experimenters who use different physical layouts may continue to find different empirical values for G.
