Research and reference that you may want to look up
For the people who follow me you know we've been doing experiments on crystal batteries I wanted to let you know why first one that you see the picture above these crystal batteries have a long running life.
So long we had to investigate. Now let's jump a little bit so we don't get bogged down in all the finer details let's talk about the electrolyte and how to make asolid-state electrolyte
Now when you learn to take advantage of this recipe for making your own Play-Doh you can add in your recipe for making a crystal battery remember the reason why Play-Doh is used is before cuz of its salt contents.
This is the most common recipe for making a crystal batteries but keep in mind that these recipes have added other elements to improve or not improve you will have to discover for yourself. Let's give you a hint in a clue on what actually is a crystal battery?
People who know me and who has followed me has heard me State many times I am the creator of overunity, they also hurt me state that overunity is not more power out then you put in. That's impossible but if you think you can please demonstrated with two equal cups of water pour water into one of the class and then attempt to get more water out then you put in the glass if you do this please put this on YouTube for the world to see, that definition of over Unity is fake and stolen but I digress.
I also am the inventor of tri-cycle physics combining combining three elements to create something new you've already heard me State two of those elements so let's add one more to complete our project
Zamboni pile - electrostatic batteries that recharges itself from the atmosphere or a static electricity it has no electrolyte so therefore now we're going to use it as a circuit between your Crystal battery layer and then build it just like you would build a voltaic pile let's give you an example on what are circuit batteries look like=
So what would this look like above is the crystal battery which has the Zamboni_pile in the middle of them the prongs are protruding from this type of batteries
Let's give you an idea of a complete finish battery when we're done with it remember this just is an illustration and yes wires will be protruding from this prototype so this should give you an idea on what we want it to look like changes may happen but illustrations give you an idea on where we're going with it
The picture below is a prototype to see if this Zamboni_pile can push any electricity into n ordinary battery it was a complete success the small motor at the top of the popsicle stick would not run on the Zamboni_pile cut energy was pumped into a regular batteries and it had enough amps to run the motor over and over again around ten thousand times and Counting it's been running for 6 months now just charge and discharge over and over sometimes I even left the switch on the on position to completely drain all the energy in the batteries overnight and when switch off ,sure enough it starts to recharge. yes to this means if we do the small salescells in a Voltic pile and compress the ordinary batteries in between that we can build a battery that self charges.
I could tell you more but we will save it for another blog it's a lot of details we left out but keep in mind we are using these batteries today and I'm skeptical of showing too much people like to take your ideas and cleaning them for yourself like my
over Unity Theory.
My theory of it is here and more info about graphite based thermoelectric batteries can find here. With respect to replication this intriguing video of famous Russian inventor Victor Petrik may be of particular interest here: he creates a thermoelectric battery just from scratch in few minutes before eyes of surprised visitors. This indicates that this effect may not be actually difficult to replicate even without using of expensive silicone wafers. The silicone may be actually suboptimal after all - even the inventor of these cells recently switched to a silicon-carbide. Victor Petrik uses just a piece of molybden sheet or nickel foil, I think. The usage of silicon-carbide or high-gap width materials in general in combination of low-gap width graphene can have certain meaning in the theory of its working.
In general I'd recommend to polarize the graphene layer with using of external voltage or with precharged electret (as McCarthy from Steorn did use), because I think that this effect actually runs on the voltage gradient formed artificially or in contact of graphene with another materials and it shares some similarity with so-called captret. In essence, the graphite layer works as a myriad of tiny charged capacitors in serii i.e. nano-captrets . The narrow space between graphite layers just enables to decrease working voltage with compare to captret and to increase the current.
Pint and his colleagues decided they wanted to make silicon work. So they coated a piece of it in carbon to protect it from reacting with other chemicals and then heated it in a furnace to seal the coating. That's when an unexpected development occurred: the coated carbon turned into a nanometer-thick layer of graphene. Just that thin layer of graphene boosted the amount of energy the capacitor could store by a factor of 100.
