Are Energetic Storage Fields the Future of Information Transfer?

In summary, the conversation discusses the concept of energetic storage fields and the possibility of using a stronger, spherical energy field to contain weaker energy carrying information in a loop. This idea does not involve any physical storage devices, but rather relies on continuously providing power to the outer loop. The conversation also touches on the potential of man-made morphogenetic fields and the idea of using code from beyond science to fill a void in life.
  • #1
Why
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Energetic Storage Fields?

We all know information can travel via waves ( radio, television, cell phones),
what is the feasibility of a stronger, sphericaly moving energy field containing a weaker energy carrying information in a loop. An energetic storage field? A man-made morphogentic field?
A loop within a loop...no hard drive, disk, or anything physical.
http://bestanimations.com/Science/Science-01.gif
 
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  • #2
that would be great, but

you would have to continue to feed power to the outer loop or you loses your entire storage mechanism.
 
  • #3
I canot tell you everything. Everything is possible we are now so advanced we can compute to infinet so go out side and injoy life once you find what you are looking for it not really what it is it's somthing else to fill the void it's called the code @ www.beyond-science.com[/URL]
 
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1. What are energetic storage fields?

Energetic storage fields are areas or regions where energy is stored in a variety of forms, such as electrical, magnetic, or mechanical energy. These fields can be found in various natural and man-made systems, including batteries, capacitors, and magnetic materials.

2. How do energetic storage fields work?

Energetic storage fields work by storing energy in a specific form, such as electric charge or magnetic alignment, and releasing it when needed. This can be achieved through various mechanisms, such as chemical reactions, electromagnetic induction, or mechanical compression.

3. What are the benefits of using energetic storage fields?

The use of energetic storage fields has several benefits, including efficient energy storage and release, portability, and the ability to store energy for extended periods of time. They also provide a reliable and stable source of energy for various applications, such as in renewable energy systems and electric vehicles.

4. Can energetic storage fields be used for renewable energy storage?

Yes, energetic storage fields can be used for renewable energy storage. They can store energy generated from renewable sources, such as solar or wind, and release it when needed. This helps to balance out the intermittent nature of renewable energy and provides a more stable energy supply.

5. Are there any potential drawbacks of using energetic storage fields?

One potential drawback of using energetic storage fields is the limited storage capacity and the need for frequent recharging or replacement. Additionally, some forms of energy storage, such as batteries, can have environmental impacts and require proper disposal methods. There is also ongoing research and development to improve the efficiency and sustainability of energetic storage fields.

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