<font color="pink"><font face="Comic Sans MS"><center><b><font size="4">The form of a particle in my Fractal Foam Model</font id="size4"></b></center>
I may have a partial answer to one of the questions I posed in my last post. Let’s think, for a moment, in two dimensions. Imagine a 2D random foam on a sheet of paper; now place a lens on the paper with a flat side of the lens down and a convex side on top; the mean size of bubbles behind the lens will appear larger than elsewhere. This could be a random variation in bubble size; after all, we are talking about a random foam of infinite extent.
Now, move the lens across the paper; this illustrates how a particle might move like a wave thru the foam. Place two such lenses side-by-side and let them orbit around a common center; this illustrates how particles, driven by Lesage-type forces, might orbit each other to form larger particles. I’m just guessing that a mathematical model of this arrangement might reveal the true nature of inertia and momentum.
I do not know, yet, whether a concave lens is a better illustration; it depends on whether the speed of P-waves thru the foam would be faster where the mean bubble size is larger or smaller. I’m fairly sure that it takes a more complex shape to accomplish fusion or fission of the P-waves (necessary to explain Lesage-type forces); so the true picture of a particle is probably much more complex. At least, this oversimplified illustration explains how a particle can move thru the ether unimpeded, without friction and without leaving a wake or dragging the ether with it. It also might explain how particle motion resembles wave motion and why a particle cannot move faster than the speed of S-waves in the ether—which I believe is the speed of light.
<center><b><font size="3">Warped space</font id="size3"></b></center>
The above illustration can be extended to large concentrations of particles to explain how space can be warped, as it is in <i>GR</i>; maybe space warping is not just a mathematical 4-space figment of the imagination, after all. I believe space, as we know it, is defined by the concentration of bubbles in the ether.
Suppose from an exterior point of view, two cubes appear to be of equal size, but in the center of cube #1 is a spherical region of smaller, more numerous ether bubbles; the ether in cube #2 and elsewhere in the vicinity is uniform. Cube #1 contains more ether bubbles, and therefore more space, than cube #2. From the viewpoint of an observer in the center of cube #1, the faces of the cube are bulged outward, and cube #2 is distorted and is smaller than cube #1.
Note: I am not deliberately trying to rescue <i>GR</i>; I am simply observing a possible similarity between it and my own model. Anyway, I have always believed the difference between <i>GR</i> and <i>LR</i> is merely semantic and of no real consequence. TV objects that <i>GR</i>’s warping of space is purely mathematical and lacks any material significance. In my Fractal Foam Model, apparently, the warping of space <i>does</i> have a real material significance; I cannot say whether my version of warped space is mathematically equivalent to that of <i>GR</i>. Like Einstein, I must rely on mathematicians to turn my imagination into something more rigorous—any volunteers? </font id="Comic Sans MS"></font id="pink">
