Space Eagle Productions

Theory About the Magnetic Field and Its Effect On Bioelectric Organisms

Look at how the Native Americans lived.  They only used what they needed.  Corporations, on the other hand, take all they can get their hands on.  It's because of the excesses that the earth's natural balance is upset now.
Since we are bio-electric, it affects humans as well.

When the balance of the energy of the earth is upset enough, it will lead to an increase in "natural disasters."  Because we are bioelectric, it also leads to disharmony among people.

Have you noticed the increase of violence since we were young?
I'm wondering if the excesses of the corporations are responsible for creating that more than just psychologically?

It's well known that they've used psychology in commercials to make people think that they need things that they don't need.  They're always telling us that we need something newer, bigger, faster, shinier.  Still, for the energy of the masses to take such a turn toward the negative, it seems that there may be something more that has occurred.  The rhythm of the energy of the earth has changed.  The polarity of the flow has changed over time as evidenced by the lava flow reversal.

Here is some information on the electrical properties of carbon and oil:

Lava flows reveal clues to magnetic field reversals

"The scientists believe the shallow core field may play a role in determining whether the main field polarity flips while weakened or whether it recovers its strength without reversing. "Mapping this field during transitional states may hold the key to understanding what happens in Earth's core when the field weakens to a point where it can actually reverse," Hoffman says.

Current evidence suggests we are now approaching one of these transitional states because the main magnetic field is relatively weak and rapidly decreasing, he says. While the last polarity reversal occurred several hundred thousand years ago, the next might come within only a few thousand years."

Condensatory/Paper and Oil Capacitors

"Many audiophiles all around the world are aware that a good NOS paper in oil capacitor gives the most natural sound compared to any new production not even speaking of any plastic capacitors. It's not our intention to give a technical explanation to this. We only recomend you to try and listen."

Oil-filled capacitor
United States Patent 4591948


"The MF capacitors presently used are mainly the so-called dry-type ones in which any electrically insulative impregnating agent such as insulating oil is not used.

Generally not only in electric capacitors but also in other various electrical appliances, the potential gradient can be made high when electrodes or electric conductors are wholly surrounded by an electrically insulative impregnating agent. That is, it is advantageous because the dielectric strength of electrical appliances can be improved. Furthermore, if the impregnating agent is properly selected, the high-voltage withstanding property can be much improved.

Accordingly, the so-called oil-impregnated or oil-filled MF capacitors are more preferable than dry-type ones. However, when a metal-deposited film with a polypropylene base film is impregnated with an electrically insulative impregnating agent, the sizes of the film are changed or the impregnating agent permeates through the boundary between the base film and the vacuum-deposited metallic layer. Accordingly, the metallic layer is cracked, and what is worse, the metallic layer peels off resulting into dielectric breakdown. In addition, as the capacitor is impregnated with an impregnating agent after the film is wound, if the selection of impregnating agent is not adequately done, the impregnating agent cannot penetrate sufficiently into the clearances among film layers, from which aimed effect of impregnation cannot be expected.

In the dry-type capacitors, dielectric breakdown is often liable to occur in the marginal edges or peripheries of wound metallic layers. So that, the improvement in the dry-type MF capacitors is intended to some extent as semi-dry MF capacitors, by impregnating the edge and peripheral portions of wound film with an impregnating agent leaving internal portions unimpregnated.

There is, however, a limit in the improvement effect in the semi-dry MF capacitors of the above type because it is impregnated only partially and most portions of electrode layers are left unimpregnated, and it may not be denied that the semi-dry MF capacitors are not satisfactory as compared with fully impregnated capacitors. Accordingly, various MF capacitors of impregnated type have been proposed."

Re: Why does carbon conduct electricity?

Date: Mon Mar 9 05:48:18 1998
Posted By: Samuel Silverstein, faculty, physics, Stockholm University
Area of science: Physics
ID: 889318314.Ph Message:


Materials such as metals, conduct electricity do so because when their
atoms are arranged together in a solid, they have loosely bound electrons
which can easily move through the material if an electric potential is
applied to it.

For instance, in a copper lattice, there is about one free electron
available per atom of copper for conduction, which makes it a very good
conductor of electricity.

But,carbon holds on more tightly to its electrons so they are not as free
to move from place to place as in the case of copper or other metals.
It is one of a number of elements known as semiconductors. Its neighbor,
one row down on the periodic table, is silicon, which is used for most
commercial microchips produced today.

In a semiconductor, electrons can't just flow through the material. They
have to move from atom to atom in "jumps", according to the laws of
quantum mechanics. When they jump, they leave a positively charged "hole",
which can be later filled by another electron jumping in to take the
first electron's place. Under the influence of an electric potential, one
sees a slow movement of negatively charged electrons in one direction and
positively charged "holes" in the other direction.

If you warm up a semiconductor, the outer electrons are more energetic,
and can more easily jump from atom to atom. So, the performance of many
microchips and other semiconductor devices varies with temperature, and
a carbon resistor can be used as a crude thermometer by measuring how
well it conducts electricity at different temperatures."

Had we taken an approach like the approach of the Native Americans and used only what we needed, things might not be as bad as they are now.  Let's take a look at what effect electromagnetic radiation has on plants:

The effect of electromagnetic radiation from the Skrunda Radio Location Station on Spirodela polyrhiza (L.) Schleiden cultures

The effect of electromagnetic radiation from the Skrunda Radio Location Station was studied on the vegetative growth and morphology of the duckweed Spirodela polyrhiza (L.) Schleiden plant in the next generation. The impact of plant development stage and length of the exposure period were examined. The effect of short-term (5-day) exposures of Spirodela cultures depended on the stage of development at the time of exposure. Generally, the vegetative reproduction rate was accelerated in the first 20 days after the end of exposure. Exposure of plants just beginning formation lowered the vegetative growth rate. Eighty-eight-hour exposure caused the appearance of some abnormal individuals after 30 days of growth. At 55 days, various morphological and developmental abnormalities appeared in 6–10 daughter plants from 10 exposed mother plants, compared with 0.1 plants per 10 in the control condition. Plants developed completely to daughter fronds under exposure from the electromagnetic field had a shorter life-span (67 days compared to 87 days in the control) and fewer subsequent daughters (total eight compared to 10 in the control group).

The electro-magnetic field also affects the heat balance of the planet:

Global warming and the hydrologic cycle

Starting with a review of the basic processes that govern greenhouse warming, we have demonstrated that the hydrologic cycle plays a key role in the heat balance of the Earth's surface—atmosphere system. Through the water and other climatic feedbacks, the hydrologic cycle is shown to be a key factor in the climate's evolution as greenhouse gases continue to build up in the atmosphere. This paper examines the current predictive capability of general circulation models linked with macroscale and landscape-scale hydrologic models that simulate regional and local hydrologic regimes under global warming scenarios. Issues concerning hydrologic model calibration and validation in the context of climate change are addressed herein. It is shown that the natural uncertainty in hydrologic regimes in the present climate introduces a signal-to-noise interpretation problem for discerning greenhouse-induced variations in regional hydrologic regimes. Simulations of river basins by means of macroscale hydrologic models nested within general circulation models have been implemented in a few selected cases. From the perspective of water resources management, such simulations, carried out in detail under greenhouse-warming scenarios in midlatitudinal basins of the United States, predict shorter winter seasons, larger winter floods, drier and more frequent summer weather, and overall enhanced and protracted hydrologic variability.

All these predictions point to potentially worsening conditions for flood control, water storage, and water supply in areas of semiarid midlatitudinal climate currently dependent of spring snowmelt. Little information of this type is currently available for other areas of the world. Practice of sound water resources engineering principles ought to be adequate to cope with additional hydrologic uncertainty that might arise from global warming.

Through our commercial driven habits of excess, we may be signing our own death warrant. It may be too late to prevent some major catastrophes for the human race, but changing our ways to less obsessive, compulsive, greedy, and wasteful ways may give future generations a chance for recovery. To continue in our current state of recklessness is to bring certain, eventual doom. Before you make your next purchase, ask yourself, “Do I really need it and is it really worth it?”

  Before you join a corporation's fight to deforest, drill for oil, or strip mine for coal, consider not only the impact that it will have on the planet, but upon your own body and the lives of the plants and animals on which you depend for your life.