Global Free Energy Blog

One day 2LoT (2nd Law of Thermodynamics) will be known as 2ToT (2nd Tendency of Thermodynamics). My diode research has proven the 2nd law of thermodynamics is a tendency, not a low.

Please help! You only need to turn off the lights for one hour on this Saturday March 28th at 8.30PM your time, local time –>

http://scitech.blogs.cnn.com

http://en.wikipedia.org/wiki/Earth_Hour

http://www.earthhour.org/home/

If you missed it, then it’s never too late to make up for it! 

Thanks for help our World!

Still constantly running simulations on two computers. Each sim can take anywhere from a few hours to a day. During each sim I’ll often add a feature to the software that will allow the software to be a bit smarter, require less of my attention. It’s almost to the point where it can run for months without my aid.

I just removed the ferrite PM’s from the horseshoe PM to test it again. It appears to be even more notably stronger, but since my gauss meter chip burnt up, I cannot say for certain. All that can be said for certain is that before starting this test yesterday the horseshoe PM was almost 100% demagnetized, almost undetectable, and now it’s about as strong as an alnico PM.

Now I will leave the ferrite PM’s off to see how long it takes for the horseshoe PM to demagnetize due to ambient thermal energy. My best guesstimate is that this experiment will take longer than I have time. A simple grasp of Gaussian distribution tells me that because the energy level required to flip the ferromagnetic atoms back might be so high that on average it could require years for ambient thermal energy to spike that high.

Yesterday I just did another long term magnetic viscosity test –>

1. I took a dead horseshoe PM (either alnico or hard steel) that had hardly no strength. Difficult to even detect.
2. Placed two ferrite PM’s on each end of the horseshoe PM.
3. Remove ferrite PM’s in ~ 30 seconds.
4. Measured horseshoe PM. No measurable difference.
5. Placed two ferrite PM’s on each end of the horseshoe PM.
6. Remove ferrite PM’s in a few minutes.
7. Measured horseshoe PM. Slight stronger.
8. Placed two ferrite PM’s on each end of the horseshoe PM.
9. Remove ferrite PM’s in ~ one half an hour.
10. Measured horseshoe PM. Significantly stronger.

This shows a long term magnetic viscosity. It’s amazing how slow some magnetic materials react to change. Steps 1 – 4 are amazing in that it reveals the slow process. The reason this occurs is there are wide range of energy levels within the material. IOW, the energy required to flip some ferromagnetic atoms. The applied field alone is by far insufficient. This is understood when magnetic material is child to extremely low temperatures. While chilled, the magnetic materials coercivity significantly increases, and I’d bet the farm so will the long term magnetic viscosity. It is the vibrating ambient thermal energy that does most of the work in flipping ferromagnetic atoms. Charts on NdFeB PM’s show that with an increase in temperature will decrease the coercivity.

What’s occurring in the long term magnetic viscosity experiments is the energy level required to flip the more difficult ferromagnetic atoms is significantly higher than the average ambient thermal energy. Ambient thermal *noise* energy is close to a guassian distribution. If we were to view a particular ferromagnetic atom, we would see it randomly vibrating– ambient thermal energy. If we were to display such movements on an oscilloscope, we would see the energy level randomly rising, falling. The peaks are also randomly. Within the millisecond it may peak to a level of 1. Within a second it may peak to a level of 10. Within 1 hour it may peak to a level of 30. It’s purely random, but Gaussian distribution shows the probability of such and event occurring within a given time period.

So in my horseshoe PM exist a varying amount of ferromagnetic atoms where some are extremely difficult to flip, some are easy to flip, and with a wide range in between. The difficult atoms are mostly the ones that stick, that make it a PM.

I’m wondering, is it possible to use this horseshoe PM to test my Free Energy design 1? Could the “free energy” effect due to magnetic viscosity overcome all of the losses in eddy currents and coercivity? A simple test would be to ***slowly*** magnetize two of such *separated* horseshoe PM’s, then quickly move both horseshoe PM’s together such that they attract. Then use a big coil, shorted out, to appreciably capture the energy as both horseshoe PM’s slowly demagnetize. Since this material has incredibly long term magnetic viscosity, you would not have to move the two horseshoe’s together that fast. Although, it could take months for both horseshoe PM’s to slowly demagnetize! Hmm, perhaps not such a good experiment.

During this time of economic difficulties the non-profit animal rescue organizations are in desperate need. I would highly recommend the national organization, ASPCA, which was founded in 1866 –>

http://www.aspca.org

If you can, ***please*** help those who cannot speak. Animal cruelity is vast and widespread.    People can donate, or become a volunteer at your local ASPCA. They are a national organization.

The fundamental secret to ambient thermal free energy (term used loosely) is TIME! Simply stated, the rectifying element must be able to react faster (time unit) than the noise source.

Diode Example: The semiconductors transit-time must be low enough such that it responds faster than the noise source. For example, the SMS7630 microwave zero bias diodes have a transit-time of 10ps (pico seconds), thus giving the diodes response near 100GHz. The SMS7630 diode has a total capacitance of 0.3pF. If we take a look at the noise spectrum of the kTC noise from 0.3pF (Vn = sqrt[kT/C]) at room temperatures we see the thermal noise drops off far before 100GHz, meaning that the diode has far better response then it’s own noise. As to why the transit-time response is faster than the noise is answered by quantum physics.

One mistake made by scientist that I’ve talked to is in assuming the existence of ***white noise.*** In the real world there’s no such thing as white noise. White noise has infinite bandwidth. According to simplified theory, white noise is 100% unpredictable. IOW, the signal at any given moment could instantly change, and thus the rectifying element has no chance of rectifying the noise. Nothing could be farther from reality, as all noise sources even down to the fundamental free electron have capacitance. The thermal noise across a source is equal to the square root of kT/C, where C is the capacitance. There is no such thing in real life as “white noise.” Thus, the noise cannot instantly change from say 10uV to -7uV. The change occurs over time, and the rectifying element can react faster than the noise fluctuations. The diode, a dynamic resistor, can react fast enough to rectify Johnson noise.

2LoT (2nd Law of Thermodynamics) is a tendency, not a law.

If anyone sees anything unusual with the website then please contact me. Last night I noticed every page on my website, except the homepage, did not respond to custom changes made to the php scripts. It took half the day to discover that someone modified the web servers .htaccess file to redirect traffic to another php file. So once again the site was hacked! I’ll just have to closely watch the site.

While the sims run in the background, I’ve spent most of my time fine-tuning the new website, which is using WordPress. So far I like it far better than drupal, and all of the others I’ve tried over the past month.

Added tags to blog posts. Each blog post has tag(s) associated with it. See the title “Tags” in the right column –>