How to generate electricity from dark and cold weather.

Dark Energy Project

Plans to build a circuit that generates clean, limitless power from the cold and dark weather

By Jean-Pascal Remon

I share this with you all and the world in a hope that someone, someday, can engineer it, and provide a luminous beacon of hope amidst the darkest of the arctic nights. Free energy is a gift to humanity.

The challenge

I woke up with a question about a month ago.

Could it be possible to generate energy (electricity) from the cold and dark arctic nights?  Could we generate electricity without solar panels, diesel generators or windmill?

Lo and behold… YES! Yes to both! The Seebeck effect, some Nik Tesla’s wisdom and some basic physics law make it possible! It is possible to turn cold weather and dark skies into… electricity


Nicholas Tesla was a genius at… hiding his real plan in his deposited patents. Here, from his own words, in patent #512 340: “The effects of self-induction, above referred to, are known to be neutralized by proportioning to a proper degree the capacity of the circuit with relation to the self-induction and frequency of the currents. […]”

“I may wind any given coil either in whole or in part, not only in a specific manner herein illustrated, but in a great variety of ways, well known in the art, so as to secure between adjacent convolutions such potential difference as will give the proper capacity to neutralize the self-induction for any given current that may be employed.”

It was only while watching the Infinity War – The Avengers that I finally got it: Tesla was talking about a Mobius structure!  Goddamn it!


Before jumping into the secret, let’s keep in mind that: “Charged particles, which were caught in the magnetic field of the earth, can move on a Möbius band” (IEEE Transactions on Plasma Science, volume. 30, No. 1, February 2002). It is a critical part of the puzzle. 


Solution

A Seebeck electricity generator using a copper/graphene Mobius Strip, or rather, multiple superimposed 540º (or 1 Pi might be fine) Mobius strips made out of copper (section exposed to the cold) with a graphene section exposed to the hot side. The copper part is to be exposed to the cold. See figure 1.1 below.

The structure would be made of multiple Mobius strips but without them touching each other (separated by ceramic brackets). They are connected in series to a supercapacitor and regulator.

Electricity is generated according to the Seebeck effect. The isolation wall could be used to store the Peltier module to regulate small fans or low voltage modules (Arduino, R.Pi).

A quantum well with Rashba potential could be generated by the flow of magnetic current going from the graphene to the copper, achieving zero non-magnetic resistance (neutralizing self-induction, therefore increasing current flowing through the Mobius strip, as seen in Tesla’s patent mentioned above). The use of Mobius strip for graphene structure might increase the current flow, as some scientists discovered when using graphene nanoribbons with chiral twisting.

The Quantum hall effect might be used to accelerate the flow of current at the edge of the Mobius strip. Small magnets could be inserted in the isolation wall to this end. Could a hall effect accelerates the particle through the structure and raise the current generated? This needs to be tested out.

The hot temperature on the graphene side will be coming from cooling pipes from diesel generators or steam pipes.

The cold is obtained from water, or the outdoors (sub-zero temperature almost year-long above the 66th parallel).

The electric potential is realized by the Seebeck effect. The Mobius strips amplify the flow of energy. To achieve an interesting energy potential, multiple strips are to be connected in series. Copper and graphene are used for they have amazing electromagnetic properties.

Figure 1.1.

Figure 1.2 and 1.3


Below: hot pipes (steam, water, coolant) passes between layers and layers of Mobius strip. Alternatively, even simply exposing one side to a warm house (+24C) and the other side to a cold exterior (-40ºC) might generate enough electricity to be useful. Replacing a window (48” by 72”, let suppose) with a “dark energy wall” could be feasible. The more layers of stripes, the better. 

The energy potential is yet to be determined, but it should be interestingly high.

Why copper?

For its amazing thermoelectric properties.

Why a mobius strip? T

o increase the flow of energy, and cancel self-induction.

Why a quantum hall effect?

To channelize the flow of electricity and raise its current (to be tested).

How to make it?
We need a machinist to make a Mobius strip half-copper, half-graphene. We need to separate both sides via a thermo-barrier. One side has to be exposed to the cold, and one side to the hot.

The ground cable is at the end of the cold side, and the positive a the end of the hot side. The difference in temperature creates electricity that flows through the strip. It is the difference in temperature that creates energy. We then collect it via supercapacitors. 

Cheers,

JP

Jean Pascal