I have started reading the debate regarding a fusion core sun versus the iron core sun. The proponents of the fusion core point to the crab pulsar as how a neutron star operates.
Since it is all theory, I would like to ask a question?
Could a pulsar simply be a star which is reversing its magnetic poles very quickly?
Living rurally I am very aware of the electromagnetic signature of electricity reversing direction in an electric animal fence. As you drive by you can hear the electromagnetic signature on your AM radio popping with each surge of current.
With that in mind I would look towards our sun for an electromagnetic signature change when it changes poles every 11 years. Is there an electromagnetic “pop” of some duration as the sun’s poles reverse? Does the profile of our sun’s electromagnetic “pop” mimic that of a pulsar only much slower? Thirdly, are pulsars simply stars reversing their poles very, very quickly?
From the Iron Sun debate only one thing comes to mind. For the sun to be fusion cored it would have to be a pure hydrogen/helium giant. What are the chances of a gravitational body being pure anything? Common sense tells me there is a core made of heavier materials than helium and hydrogen, which would have sunk to the core of the sun, based on their density.
Possibly neither debate is fully correct, but a combination of the two.
Tuesday, October 16, 2007
Wednesday, October 10, 2007
Galactic Game of “Six Degrees of Seperation"
In the broadest of strokes, and from my layman’s standpoint, these are the broad strokes in the galactic game of “Six Degrees of Seperation”;
- 365 degrees galactic year
- ~122 degrees full solar galactic oscillation occurs
- ~61 degrees solar systems crosses the galactic plane
- ~28 degrees Earths wobble and the seasons
- ~14 degrees Sun’s degree of oscillation to the galactic plane
- ~6 degrees solar systems variation to galactic plane
- 1 degree of solar magnetic field line variance Earth reverses magnetic field
- 0 degrees largest massive extinction on Earth every ~225 million years. Start of new galactic year.
That is the whole enchilada. Kind of makes a nice symmetry doesn’t it. Earthy events can be plotted for every one of those points and their convergence from Earth's geologic record.
God!!! I just boiled down everything in the galaxy to eight lines of information. Talk about reducing intelligent thought into pabulum.
Monday, October 8, 2007
Why Does the Earth's Magnetic Field Reverse?
Scientists wonder why the earth’s magnetic field reverses on a regular basis. In the last 71 million years the earth has reversed it poles 171 times, however they do not know why. They state…
The Earth's magnetic field is attributed to a dynamo effect of circulating electric current, but it is not constant in direction. Rock specimens of different age in similar locations have different directions of permanent magnetization. Evidence for 171 magnetic field reversals during the past 71 million years has been reported.
1. The earth is a giant electromagnet. The power for this electromagnet comes from the solar winds that are composed of protons and neutrons that collect at either pole and the flowing electrons power the earth’s electromagnet field.
Why do I think that? There has to be evidence in nature to support my theory. Lets look at an actual magnetic field of a bar magnet. This is done by placing a bar magnetic under a piece of paper that has iron filings on it. It looks like this; (we have all done this as children)
Each one of those lines of magnetic field is in opposition to the next, each repelling the next in both directions. You cannot help but notice there is space between the magnetic field lines.
Now think in solar and galactic terms and the space between the magnetic field lines are immense. If the earth was an electromagnet as I theorize every time it crossed a magnetic field line its polarity would reverse. Just like this;
The Earth's magnetic field is attributed to a dynamo effect of circulating electric current, but it is not constant in direction. Rock specimens of different age in similar locations have different directions of permanent magnetization. Evidence for 171 magnetic field reversals during the past 71 million years has been reported.
Although the details of the dynamo effect are not known in detail, the rotation of the Earth plays a part in generating the currents which are presumed to be the source of the magnetic field.
I think they are making two mistakes; I believe..
1. The earth is a giant electromagnet. The power for this electromagnet comes from the solar winds that are composed of protons and neutrons that collect at either pole and the flowing electrons power the earth’s electromagnet field.
2. The earth is in a constant orbit that passes between varying lines of the suns magnetic field due to the sun changing its orientation to a galactic magnetic constant.
Why do I think that? There has to be evidence in nature to support my theory. Lets look at an actual magnetic field of a bar magnet. This is done by placing a bar magnetic under a piece of paper that has iron filings on it. It looks like this; (we have all done this as children)
Each one of those lines of magnetic field is in opposition to the next, each repelling the next in both directions. You cannot help but notice there is space between the magnetic field lines.
Now think in solar and galactic terms and the space between the magnetic field lines are immense. If the earth was an electromagnet as I theorize every time it crossed a magnetic field line its polarity would reverse. Just like this;
There would be a specific periodicity of cyclicality to this change. This timing involves how the sun changes its angular relationship to the magnetic field of the galaxy as it oscillates up and down along the galactic plane.
There is a ton of math I have to do to prove this but my pictorial example shows how earths orbit remains steady, but as the suns angle changes over millions of years the earth would shift through the magnetic field lines.
The math involves the sun’s orbital speed around the galaxy, the speed the sun oscillates up and down in its orbit of the galaxy, the distance covered in latitude, and some other items I will have to think about. But I will bet you the answer is that the earth crosses one of sun’s magnetic field lines every 415,205 years. When it crosses the line the magnetic field reverses just like any good electromagnet that is in repulsion mode.
The math will also reveal the distance between the sun’s lines of magnetism which will lead to other answers.
Sun Outer Layer Rotation Correction?
I used this animation of how our Sun oscillates up and down in its equatorial rotation throughout the year. I think I am looking at it totally backwards…
This animation depicts our sun’s change in;
Bo - the heliographic latitude of the centre of the disk,
Lo - the heliographic longitude of the centre of the disk,
P - the position angle of the north end of the axis of rotation and the apparent diameter of the Sun.
What if the sun varies very little and it is just the angle we view the sun from that is changing?
What if the equator of the sun stays nearly aligned with some galactic constant whether it be magnetic, or mass related, while our view of the Sun varies from the degree of variation of earth’s orbit to that galactic constant?
I believe that our solar systems orbit is 63 degrees out of alignment with the galactic plane.
As the earth moved up and down it would appear the sun’s equator was moving, when in reality only the observers perspective was changing.
To compound it even further… I wonder if the Sun’s core rotation is aligned with a galactic constant, while it’s outer layer rotation is more affected by the planets, and what we see in outer layer rotation is simply the harmonic pattern between the alignment of the sun to the galactic constant versus planetary rotational tug on the outer layer.
This would mean that the pattern of planets orbiting our sun could cause interaction between the sun’s core and outer layer. These variations would cause solar cycles. And when a planetary alignment occurs it offers more or less correction bringing the sun’s core and outer layer into better or worse alignment.
Is this the reason for the Maunder Minimum? A planetary alignment that resulted in a rotational correction to the sun’s outer layer that was very good.
This would mean it is the width of the planetary alignment that defines potential adjustment, distance which defines the adjustment power, AND the degree of correction (or error) imparted to the sun’s outer layer bringing it into better alignment with the galactic constant?
If you are old enough to remember adjusting points in your car’s distributor it is very similar. The closer you aligned the points to that sweet spot the better the engine ran. It is all a matter of your hand imparting correction to the points. This correlates to the planets constantly adjusting the sun’s “points” in and out of that sweet spot, and some adjustments are better than others.
Since the planets are very cyclic these corrections can be plotted and solar activity predicted. We have noticed the pattern, but have not identified the cause.
Do I have a potential cause?
Sunday, October 7, 2007
Gravitational Changes Are Dangerous
I want to do a mind experiment with you. It is simple math and will only take a minute.
Our solar system orbits the Milky Way galaxy. The “number crunchers” of our age tell us it takes ~225 million years for our solar system to make a single orbit.
We are also told that the orbit oscillates 2.7 times during that orbit above and below the galactic plane (densest part of the galaxy) by 24 degrees latitude.
We are also told that the galactic orbit is elliptical (oval), and that would mean we rotate closer and further away from the galactic core.
Now for the experiment.
If the solar system oscillates above and below the the galactic plane 2.7 times in its orbit, that means it happens every ~83 million years [ (225/2.7=83.3) ].
Now to achieve an oscillation you cross the galactic plane twice. Our solar system crosses once diving down and then once again on the way up to return to the starting point. So this means a galactic plane crossing every 41.6 million years [ 83.3/2=41.6) ].
Alright, now let’s look at Earth’s geologic record which records events in the scale of millions of years. What happens every ~41.6 million years? Let’s look at mass animal extinctions for that is a large pattern and people love to rubber neck disaster.
Our solar system orbits the Milky Way galaxy. The “number crunchers” of our age tell us it takes ~225 million years for our solar system to make a single orbit.
We are also told that the orbit oscillates 2.7 times during that orbit above and below the galactic plane (densest part of the galaxy) by 24 degrees latitude.
We are also told that the galactic orbit is elliptical (oval), and that would mean we rotate closer and further away from the galactic core.
Now for the experiment.
If the solar system oscillates above and below the the galactic plane 2.7 times in its orbit, that means it happens every ~83 million years [ (225/2.7=83.3) ].
Now to achieve an oscillation you cross the galactic plane twice. Our solar system crosses once diving down and then once again on the way up to return to the starting point. So this means a galactic plane crossing every 41.6 million years [ 83.3/2=41.6) ].
Alright, now let’s look at Earth’s geologic record which records events in the scale of millions of years. What happens every ~41.6 million years? Let’s look at mass animal extinctions for that is a large pattern and people love to rubber neck disaster.
The above graph depicts mass animal extinctions on Earth and do you notice a pattern of how frequently they happen? Yes, it happens around every ~41.6 million years.
So now we know crossing the galactic equator is dangerous.
But I bet you want to know why it is more dangerous at certain times than at other times.
The answer is quite simple. Our solar system orbits the galaxy in an elliptical (oval) orbit. Sometimes when we cross the galactic plane we are farther from the galactic barycenter (rotational point of the galaxy), but closer to the galactic core (largest concentration of mass) than others.
The closer you are to the galactic core the closer you are to more mass and the more mass the greater the gravitational influence. The more gravitational influence the more it affects Earth’s climate as this additional gravity affects our sun. The more the Earth’s climate varies the more animals go extinct.
It comes down to the chances of walking across a busy highway at 3:00 in the afternoon versus 3:00 in the morning and how that relates to your chances of being run down.
So within that ~225 million year orbit there should be one area of mass extinction where it peaks, where the galactic plane crossings occur when the solar system is closest to the galactic core.
I suppose you can see from the mass animal extinction graph above this works with the ebb and flow of our elliptical galactic orbit. Every ~225 million years mass animal extinctions peak.
The good news is that we just completed that “worst” crossing ~45 million years ago, and we are moving away from it. In ~30 million years there will another mass extinction, but less severe than the last one.
It is as predictable as the sun rising in the morning.
The best part is that these same principles work at both the galactic level and the smaller scale of our solar system which has its own mass and changes in gravity due to variances of the “solar core” and “solar barycenter” (a point just outside the solar core). This makes it possible to predict approximate climate change on Earth.
Thursday, October 4, 2007
Global Cooling Prediction
I took every major planetary alignment in our solar system going back 6,000 years and plotted it against known dramatic temperature changes on Earth. On the chart below to convert “Years BP” to something you understand subtract ~2,000.
Lines represent major planetary alignments
This should produce a cooling effect similar to the one in 332 AD, possibly a little steeper for the greater the distance from the sun the alignment occurs the larger the cooling affect on Earth. In 2040 the alignment degrees will be .5 degrees wider, but the relative distance will be 11 greater. A very similar ballpark to 332 AD.
These alignments affect the sun’s energy production as related to sunspots.
If temperatures do drop to the extent predicted it will be very unpleasant.
Lines represent major planetary alignments
What I find is that every major planetary alignment of the planets resulted in a cooling period on Earth. The critical factor is the alignment degrees and relative distance from the sun that the alignment occurred. If the alignment degrees are less than 11 and the relative distance from the sun is greater than 12 the Earth experiences a dramatic cooling. There are only two exceptions to this finding in my data, and these were periods where the major alignment was either quickly preceded or followed by a minor alignment the two events combined leading to a major drop.
Years in black font were multiple alignments that resulted in major cooling
Note: when the distance is short from the sun it takes multiple events
When you look at many of the cooling periods on the overall temperature chart some are staggered or dramatically stepped. These would correspond to quick minor alignments followed back to back.
The next major alignment is in the year 2040 and if it follows what I have found it will be a dramatic cooling.
Note: when the distance is short from the sun it takes multiple events
When you look at many of the cooling periods on the overall temperature chart some are staggered or dramatically stepped. These would correspond to quick minor alignments followed back to back.
The next major alignment is in the year 2040 and if it follows what I have found it will be a dramatic cooling.
This should produce a cooling effect similar to the one in 332 AD, possibly a little steeper for the greater the distance from the sun the alignment occurs the larger the cooling affect on Earth. In 2040 the alignment degrees will be .5 degrees wider, but the relative distance will be 11 greater. A very similar ballpark to 332 AD.
These alignments affect the sun’s energy production as related to sunspots.
If temperatures do drop to the extent predicted it will be very unpleasant.
Monday, October 1, 2007
Global Cooling Just Ahead
Below is a graphic representation of global cooling induced by fewer sunspots.
The above graph depicts sunspot counts for each year. As you can see sunspots nearly ceased just before 1645. This lack of sunspots lead to a little ice age. .
Don’t think huge ice age, think long, hard winters, cool summers, and shorter growing seasons. More like a lot of bad winters and crummy summers back to back.In my theory the planets would have to be aligned just prior to the sunspot cessation and all pulling on the Sun in the same direction for this to happen.
On August 3rd, 1642 this is how the planets were aligned;
August 3, 1642
Imagine the yellow circle is a loose fitting bottle cap and the line is your hand moving forward and rotating the bottle cap. That is exactly what the planets did to the Sun in 1642. It was a shearing force that accelerated the Sun’s rotation on its axis. The force is multiplied when the planets align like this.
Within days/months sunspot activity had ceased on the Sun in 1642 and Earth entered a cooling period. The period is known as the Maunder Minimum, but better known as the “little ice age”.
On September 8th, 2040 the planets will align again in a similar fashion and Earth will once again begin a cooling cycle.
September 8, 2040
In this depiction it is the same bottle cap only you are pulling your hand towards the cap and it spins off. In the solar world since the sun is just spinning free, the energy is imparted to its rotational speed.
How does this stop sunspots? The additional speed makes the sun spin 3-4% faster on its axis. This little bit of energy is all that is needed to stabilize the relationship between the Sun’s inner core and outer shell. When it stabilizes no more sunspots. No sunspots and the Earth cools.
Now the little burst of rotational energy does not last long and the Sun's rotationa slows down again, and Earth starts a new warming cycle.
This cycle repeats over and over, and depending on how the planets line up different levels of rotational energy are imparted to the Sun making some cooling periods a bit longer than others but there are long term patterns of warming and cooling based on planetary motion and alignment.
If nothing else; come 2040 we may be happy to have a marginal greenhouse effect in place to help mitigate the next little ice age.
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