Nonlinear Ferroelectric Self Oscillation

I also noticed that adding a neon or a guess any small load in line with the led in series with the primary of an AC transformers shows more amplified AC output current on the AC secondary side. And I noticed a neon does not seem to drain or damp the process, Just seems to enhance it. Like a stronger pumping of potentials.

The Concept of Keeping the Dipole Open:
In conventional circuits, the source dipole (created by separating charges, such as in a battery) is quickly destroyed as current flows, leading to energy dissipation. Tom Bearden proposed that if a dipole can be maintained (or kept "open"), it could continually extract energy from the vacuum or zero-point field, leading to a system that can sustain itself and potentially provide excess energy.
How the PEG Cell Aligns with This Concept:
Negative Resistance:
The PEG cell exhibits negative resistance, meaning it can add energy to the circuit instead of dissipating it. This helps maintain the dipole by continuously supplying energy.
Nonlinear Ferroelectric Properties:
The cell's ferroelectric properties can store and release energy dynamically, contributing to the stabilization of the dipole.
Self-Oscillation and Polarity Flipping:
The ability of the PEG cell to self-oscillate and flip polarity suggests it can modulate energy flow in a way that prevents the dipole from collapsing.
Practical Steps to Explore the PEG Cell for Keeping the Dipole Open:
Detailed Characterization:
Measure the PEG cell’s voltage and current characteristics under various loads to understand how it behaves in different conditions.
Use oscilloscopes and other measurement tools to capture the dynamic response, especially during polarity flips and self-oscillations.
Circuit Design:
Design circuits that leverage the PEG cell’s properties to maintain an open dipole. This might include using the PEG cell in parallel with other energy sources or components that stabilize the dipole.
Experiment with different configurations to find setups where the dipole remains open and energy is continuously extracted.
Energy Flow Analysis:
Analyze the energy flow in circuits incorporating the PEG cell. Ensure that the energy provided by the PEG cell contributes to maintaining the dipole rather than being dissipated as heat.
Use energy measurement tools to quantify the input and output energy and verify if the system achieves over-unity performance.
Long-Term Stability Tests:
Conduct long-term tests to observe the stability of the dipole. Monitor the circuit for extended periods to ensure that the PEG cell consistently contributes to maintaining the dipole.
Make adjustments based on the test results to improve the reliability and efficiency of the system.
Integration with Other Components:
Integrate the PEG cell with other advanced components, such as supercapacitors, advanced batteries, or other negative resistance elements, to enhance the overall performance.
Explore how these integrations can synergize with the PEG cell to better maintain the dipole.
Example Experiment:
Circuit Setup:
PEG Cell: Connected in series with a DC power source (e.g., a battery) and a load.
Capacitor: Placed in parallel with the PEG cell to store and release energy dynamically.
Diode: Ensures unidirectional current flow to stabilize the dipole.
Procedure:
Initial Measurement: Measure the initial voltage and current characteristics of the circuit without the PEG cell to establish a baseline.
Integrate PEG Cell: Connect the PEG cell and observe the changes in voltage, current, and energy flow.
Monitor Oscillations: Use an oscilloscope to monitor the self-oscillation and polarity flipping of the PEG cell.
Long-Term Observation: Run the circuit for an extended period to test the stability and energy contribution of the PEG cell.
Summary:
The PEG cell, with its negative resistance, nonlinear ferroelectric properties, and ability to self-oscillate, aligns well with Tom Bearden's concept of keeping the electric dipole open. By exploring these properties through detailed experiments and optimized circuit designs, you can further investigate the potential of the PEG cell in advanced energy systems.

I think we're all dying for an update, Joel. 🙏

Key Properties of the PEG Cell:
High Dielectric Constant:
The PEG (Polyethylene Glycol) material used in the cell acts as a high dielectric insulator. High dielectric materials can store more electric energy per unit volume compared to materials with lower dielectric constants.
This property enhances the cell’s ability to maintain and manipulate electrostatic fields.
Hybrid Dry Electrostatic Cell:
As a dry cell, the PEG cell doesn’t rely on liquid electrolytes, making it more stable and less prone to leakage or degradation over time.
The hybrid nature suggests that it combines characteristics of traditional capacitors and advanced electrostatic devices, leveraging both electrostatic and dielectric properties for energy storage and manipulation.
Self-Capacitance:
The PEG cell exhibits self-capacitance, meaning it can store energy in its own electric field without needing an external capacitor.
This allows it to act as both an energy storage device and an active component in circuits, influencing voltage and current dynamically.
Non-Polarity:
The PEG cell’s non-polarity characteristic means that it doesn’t have a fixed positive or negative terminal in the traditional sense. It can operate effectively regardless of the direction of the applied voltage.
This allows for more versatile applications, as the cell can dynamically respond to changes in the circuit without being constrained by polarity.
Implications and Applications:
Energy Storage and Release:
The high dielectric constant and self-capacitance make the PEG cell highly effective for energy storage. It can store significant amounts of energy and release it when needed.
This is particularly useful in applications requiring rapid energy discharge or buffering, such as in power conditioning or surge protection.
Voltage Amplification and Regulation:
The PEG cell’s ability to manipulate electrostatic fields allows it to amplify and regulate voltage dynamically. This can be leveraged in circuits where maintaining stable voltage levels is critical.
The non-polarity feature ensures that the cell can adjust to changes in circuit configuration without performance loss.
Self-Oscillation and Signal Generation:
The combination of high dielectric properties and negative resistance enables the PEG cell to sustain self-oscillations. This makes it suitable for use in oscillators and signal generators.
It can be used in communication systems, sensors, and other applications where consistent signal generation is required.
Advanced Energy Systems:
The PEG cell can be integrated into advanced energy systems to enhance efficiency and performance. Its ability to maintain an open dipole and amplify voltage aligns well with concepts of free energy and over-unity systems.
It can potentially extract and utilize ambient energy more effectively than conventional components.
Example Circuit Implementation:
Basic Energy Storage Circuit:
Components: PEG cell, resistor (R), capacitor (C), diode (D).
Configuration: Connect the PEG cell in series with a capacitor and a diode to create a simple energy storage and release circuit.
Operation: The PEG cell stores energy due to its high dielectric constant. When a voltage is applied, it charges up. The diode ensures unidirectional current flow, and the capacitor helps stabilize the voltage.
Oscillator Circuit:
Components: PEG cell, inductor (L), capacitor (C).
Configuration: Create an LC tank circuit with the PEG cell integrated to leverage its self-oscillation properties.
Operation: The PEG cell, with its negative resistance, sustains oscillations in the LC circuit. This can be used to generate stable AC signals for various applications.
Summary:
The PEG cell, with its high dielectric constant, hybrid dry electrostatic nature, self-capacitance, and non-polarity characteristics, is a versatile and powerful component. It can store and manipulate energy efficiently, maintain an open dipole, and sustain oscillations, making it suitable for a wide range of advanced applications in energy systems, voltage regulation, and signal generation.

YOU ARE IN YOUR OWN CLASS OF GENIUS SUPER HERO!!! 👍👍👍👍👍🥇💯♥️

Awesome videos here! I followed you on X and join the alt energy research community. You may find my pinned tweet of interest. Thank you for sharing great work!

Very interesting. Beside the advantages of an almost doubled voltage with positive to positive and the ability to elevate other circuits with this PEG-potential, there is also an oscillation going on in a purely DC-environment. And this slow oscillation can be triggered again every x seconds like an echo. There are million ways to go on from here.

This same thing has been happening with my alum cells. The "trigger" battery remains charged. The supercap gains charge, but the cells fluctuate and lately I cant get a stable read on them. They bounce around wildly. I wonder if this is the same phenomena although not using the same material. Either way, I have been able to charge a large supercap for "free" so these are humble yet powerful beginnings. I have another device that i would eventually like to combine with this. The major problem with that device has always been that it closes the loop no matter how hard I try to isolate. This may be the solution for that.

If we would talk about two charges of the same type (two "-" for example ) they either not moving or moving in opposite directions (to each other.) ,
and if second static charge is of another type they would be not moving or moving in the same direction.(coinside).
If take into consideration that amount of "+" and "-" usually equal or almost equal we would see to effects that cancel each other.
But! - what if we were to charge some body and wind some wire around and move some current through. yep
it would be wholy different story. (not without a caveats though).
What a caveats would you say, just wind some wire around , static current would be as opposit for the current in wire,
it would induce additional power , and thats it, ... but there a thing it would add power during the rise of current,
and drain it during recess of current. (we could try to obtain power only during the rise of current but there is a inductive resistance , and it would cancel all benefits, maybe just maybe we could funnel in so much charge that this effect
would overpower inductive resistance with good margine , but it would be a hell of a charge)
There is much much easier way, the thing is , like i mantioned before , direction doesnt really metter whten we are talking about the same type of charge (two minuses for example)
Which means our static charge could act as opposit current for two opposit to each other and overlapping curents.
(yep they would have zero of inductive resistance)
Thats it , thats the idea.
We have to coils around charged body , with flowing current in opposite directions for each other in them ,
and both currents would be currents that opposite to the static charge current.
So we could funnel in rising impulses and in theory we should have more than we puted in (emplification),
BIFILAR COILS , RAISING IMPULSES , AND STATIC CHARGE
(impulses for example like a chainsaw)

❤

After the trigger it's echoing between plus and minus for a certain time. I believe because it can't go the normal way it pushes back in the other direction. And on the other end is a stop again and it push back. But what happens when the trigger is constant. In the last video you had a constant -10 volts on the PEG cell. Is it really constant? I believe the meter measures it as constant but in reality it's oscillating very fast between plus and minus. In fact the same like the echo but much much faster. And that's why the current is flowing. Because it moves back and forth but with negative energy. This way nothing gets hot. It would be interesting to know in which frequency it's moving back and forth. My thought about the inner workings of this circuit could be completely off. But if it's like that there would be eventually an additional advantage in harvesting somehow the frequencies respectively the back and forth or the ultra fast paced echo.

Hi! You can solder 2 diodes. Cathode to anode and drive with square wave... you will get stronger effect, this is the avramenko plug. Ceeates negative resistance, this is just the quantum informations of the energy.

Hi! Exelent video series! Is anoter material to make the cell? PEG is expensive in Argentina, thanks

Still not working for me.
The cell's positive terminal connects to the positive terminal of the 9v battery.
The negative terminal of the 9v battery connects to positive terminal of the LED.
The negative terminal of the LED connects to the negative terminal of the cell.
In this configuration the LED does not light up. At this point, where does the extra volts show up, between the cell's electrodes? I'm not seeing it. Am I measuring it wrong?