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Old July 10th 03, 03:33 AM
ralph sansbury
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Default Electric Gravity&Instantaneous Light

http://www.bestweb.net/~sansbury/book01.htm
http://www.bestweb.net/~sansbury/book01.pdf








INTRODUCTION

One could characterize this book as being about evidence for
charge polarization inside electrons and atomic nuclei and what
that implies, particularly with respect to gravity and light and
the effect of gravity on light. But it can also be characterized
as being about the two most damaging mistakes in the history of
physics.

The first was Roemer's so called measurement of the speed of
light in 1676; the second was Kaufmann's 1903 measurement
of the apparent increase of the mass of beta electrons as their
velocity increased. The experts of the times in these specific
sorts of measurements, in each case, were ignored. Preference was
given to the opinions of a larger number of scientists whose
expertise lay elsewhere

The damage caused by these mistakes continues to undermine our
basic understanding of electromagnetic radiation, gravity and the
atom. Recent advances in optics and electronics provide the
necessary tools to correct these mistakes and put physics back on
track.

When we do so, we shall see that gravity is a form of magnetism
and that magnetism is a form of electrostatic force involving
charge polarization inside electrons and inside atomic nuclei. We
shall see also that the delay associated with electromagnetic
induction and radiation is due to the reaction time of charge
polarization inside electrons and atomic nuclei of the receiver.

Let's summarize briefly the two mistakes. First, Roemer's
measurement of the speed of light required that light be a wave
front or a group of moving particles while Bradley's and Fizeau's
light speed measurements allowed light to be interpreted as the
cumulative effect of instantaneous forces at a distance. That is,
Roemer's measurement required that reflected sunlight, reflected
from the surfaces of Jupiter's moons, traveled as a wave front or
particle for about 40 minutes using Bradley's value (or 55
minutes using Roemer's value) until it reached the earth. By
which time an observer on the earth would have moved with the
earth a substantial distance, frequently from under clouds, to a
location with an unclouded view of the night sky. That is
Roemer's measurement did not require constant exposure to the
light source.

However, recent light speed measurements suggest that constant
exposure is required and that the cumulative effect
interpretation is closer to the facts.

It is necessary to point out here that communications with
distant satellites do not confirm Roemer's measurement as they
would seem to at first glance. These communications involve so
many repetitions of each faint bit in each signal so that the
signal can be distinguished from noise, that comunications delay
from such needed repetition is typically greater than the delay
from the speed of light; so that the delay implied by the speed
of light is assumed but not tested in these cases. Also the
control of a distant satellite is based on just previous
communication with the satellite. It is the difference in time
between successive communications which is important not the time
between when the signal is sent from the satellite to when it is
received on the earth etc..

Someone with a GPS device, complained to me recently that signals
received from several satellites at slightly different times by
his GPS device which could then compute his position, was a
conclusive argument against the cumulative effect interpretation.

I could only reply that in these cases the time differences were
of the order of milli to nanoseconds; that during such small
intervals of time the cumulative effect and the moving
wave/particle interpretation of light give the same results.

He offered no counterargument but he would not be persuaded.

The cumulative effect interpretation makes Einstein's valiant
effort to save Maxwell's theory from the Michelson Morely
experiment, with dilations and contractions of space-time,
unnecessary. In fact if we view light as the cumulative effect of
instantaneous forces at a distance Maxwell's premise of an
invisible massless field conveying electric and magnetic
influences from a source to a receiver is also rendered
unnecessary.

The problems of the photon theory, of the wave photon duality or
of the probabilistic photon are similarly avoided. The
probabilistic photon theory begs the question of what actually
happens in the process of emission and reception of a photon.
Also and perhaps more importantly the photon theory does not
explain how a photon can move like a particle and yet not have
the other characteristics essential to the definition of a
particle, like its mass (as measured by a mass spectrometer etc).

One might object that a cumulative instantaneous force theory
does not explain how forces can occur between objects which are
not touching. The response to this is that sure, human beings
must touch things to move them. But the primitive human
experience includes magnetic and electrostatic attractions and
repulsions between things which are not touching.

Consider the force between charged particles such as leaves of
tin foil on a simple electroscope. The leaves are fastened
together at the top by say an aluminum paper clip. The aluminum
clip and the top part of the leaves are charged. The bottom parts
of the leaves are free to move apart and they do because
similarly charged particles repel each other. The formula for
this repulsion is an inverse square force similar in form to
Newton's gravitational force. It is not necessary here to
postulate a field or the movement of photons.

In fact if we were to postulate the existence of undefined
entities unnecessarily we would stand in violation of the
scientific method specifically of Occam's principle of parsimony.

Hence the cumulative effect interpretation of light would, having
fewer assumed entities, be preferable to the present theory of
light if we could show Roemer's so called measurement to be due
to other causes. We will discuss these causes in the section on
light speed measurements.

The second major mistake in the history of physics has to do with
the apparent increase of mass of beta electrons as they
approached the speed of light. Beta electrons (electrons emitted
by nuclei of radioactive atoms) of various speeds near the speed
of light were observed. Their increasing responsiveness to a
magnetic field as their velocity increased was seen,
unexpectedly, to slack off when the velocity increased beyond a
specific amount. The rate of increase of the response, as the
velocity increased, unexpectedly decreased. Instead of being
attributed to changes in some previously unobserved quality of
magnetic responsiveness, these changes were attributed to
increasing inertia or mass. The force producing the velocity
somehow after some threshold point produced an increase in mass
also.

Kaufmann, the one person who had most familiarity with this sort
of experiment objected that the data seemed to require different
values for the mass in different directions. But his objections
were ignored in favor of the simpler explanation offered by
Special Relativity whose success in explaining the Michelson
Morely experiment was in its favor.

We will discuss Kaufmann's reasons later and show that a better
explanation is that there is a change in magnetic responsiveness
as the speed of a charged particle increases to the speed of
light. The explanation is better because it requires fewer
assumptions and is consistent with new discoveries in nuclear
physics.

The increasing number of premises and circumlocutions in modern
physics are due to the mistaken interpretations of Roemer's and
of Kaufmann's measurements. When Faraday and Maxwell first
imagined invisible lines of force, wheels and ball bearings to
help them understand electromagnetic induction and radiation as
implied by Roemer's experiment, it was not inconceivable that
such things existed. But even during Maxwell's lifetime
improbable implications of such entities became difficult to
ignore. For example the invisible and perhaps vacuous field
medium carrying light would have to have the rigidity of iron.

Despite such problems with field theories, the apparent lack of
any alternative to explain the phenomena of radiation, e.g.
Roemer's measurement, has led to even more extravagant claims for
fields.

Physicists like Witten at Harvard, for example believe that
latent energy and mass may exist in a complete vacuum, in
massless space; that the existence of fields implies such a
possiblity. Witten calls these vacuous latent mass energy things,
strings and they are somewhat similar to Wheeler's quantum foam.
And other physicists like Kip Thorne at Stanford extending the
ideas of John Wheeler, believe there are wormholes in space-time,
since space-time near a large dense star could be severely bent
out of shape; also perhaps, that these wormholes may lead to
otherwise invisible universes. The mathematical complexity of the
justification for these speculations confounds journalists who
anyway have to be more concerned with catchy phrases and
startling images than with scientific clarity.

But one doesn't have to follow a lengthy mathematical argument to
see the probable fallacy in such speculations. Regarding latent
energy and mass in vacous space. Our only experience of latent
energy and mass is in the presence of other mass and not far from
such masses, in empty space. For example, radioactive nuclei
produce charged particles of lesser mass that move at high
velocities. These particles are visible as they move through
cloud chambers and cause condensation around them in their
successive positions in the moist vapor of the cloud chamber. But
sometimes, uncharged particles may be ejected and soon break up
into charged particles that seem to appear out of nowhere. But
such things are not observed to occur in vacuous space far from
the mass of an excited atomic nucleus and so may be the breakup
of an ejected particle of net zero charge.

The small Casimir attraction between uncharged metal plates and
the Aharanov Bohm shift of electron beam interference effects can
be attributed to charge polarization inside moving electrons and
atomic nuclei and not to latent energy in the vacuum. Similarly
the zero point energy of electrons etc can be attributed to the
orbital system within electrons etc.

Regarding wormholes, black holes, and other implications of the
General Relativity assumption that mass distorts space-time and
the premise that the density of imploding mass can increase
beyond specific limits as implied by quantum mechanics:

The situation is analogous to a rubber band stretched to the
limit. One cannot apply indefinitely a linear formula to describe
the amount of stretching produced by a given force on a rubber
band. At some point the band loses its elasticity and the
relation between force and stretch loses its linearity. And at
some point the band breaks but the formula keeps grinding out
numbers. The linear formula alone is not enough to tell when the
band breaks. When extrapolations claim the existence of stranger
and stranger phenomena, it is time, isn't it, to question the
validity of the extrapolation and the applicability of one' s
basic assumptions and theory.

Necessary information is lacking in black hole and wormhole
speculations based on the predictions of equations that are
observed to be valid for some values of the independent
variables. Will these same formula work for unobserved values of
the independent variables? Probably not, especially if the
predictions are counter to our previous experience of similar
things and events.

Let us look more closely, also, at the assumptions required for
black holes and wormholes. Regarding General Relativity: the
effect of the sun's mass in delaying slightly the time when the
eye recognizes light from a distant star can be attributed to the
effect of the sun's mass on the eye or other receiver of the
radiation; that is, we do not have to assume that space time is
bent by large masses as assumed by General Relativity. Similarly
the precession of the perihelion of the planets may be attributed
to a torque interaction between the planets and the sun as
dipoles; we do not have to assume that space-time is bent. By
dipoles here I mean electrostatic dipoles and the evidence of
such dipoles will be shown in a later section dealing with
gravity.

Regarding how much a star can collapse given the forces of
repulsion between atomic nuclei and parts of atomic nuclei, the
evidence of neutron stars with densities one hundred trillion
times that of water or of the sun may point to even greater
densities and black holes and singularities. But as we have said,
when limits are approached and extrapolations are made of things
happening that are unlike anything we know, it is time to
reassess the boundaries of the theory that leads to such
extrapolations.

The reassessment involves observing evidence for charged orbiting
particles inside electrons and atomic nuclei and what that
implies, particularly with regard to accepted hypotheses
regarding 1)Ampere's theory of magnetism, 2) the wave,photon and
probabilistic photon theories of electromagnetic radiation, 3)the
quantum theory of atomic energy levels and of magnetic phenomena,
4)exchange forces and the quark theory of Gell Mann, 5)
Einstein's special theory of relativity and mass energy
transformations 6) Newton's theory of gravity and Einstein's
general relativity theory.

No one after reading the evidence and the arguments in this book
can avoid the conclusion that all the forces of nature including
gravity, magnetism and the weak and strong nuclear forces are
derived from a single force, the electrostatic force.