Quantum Electret
Today, I'm eager to share insights into an advanced exploration of quantum electrodes, which are characterized by their utilization of solid-state electrolytes, such as crystals or polymers. In my endeavors, I've primarily engaged with polymer-based electrolytes. A remarkable aspect of these cells is their inherent capacity for self-charging at their intrinsic voltage of pure potential. This capacity is facilitated by the solid-state electrolyte's ion flow, intertwined with the initial ambient moisture and the moisture present in the mix prior to its solidification. Moreover, the distinctive electron flow phenomena, including quantum tunneling, electrostatic, and triboelectric effects, significantly contribute to this process.
As we delve deeper into the nuances of these cells, we uncover that the solid-state electrolyte mixture initially presents as a gel-like paste. This mixture undergoes a gradual solidification, driven by natural potentials. Crucially, upon complete drying and the evaporation of moisture, the material undergoes a transformation into a hybrid solid-state electrolyte and dielectric. It is at this juncture that a gradual accumulation of an electret effect occurs—by deliberate design. This transformation is fundamental to the creation of the potential difference and the electric field within the cell.
To further refine and enhance the properties of the cell, a conditioning process can be implemented. This involves heating the dried solid-state electrolyte in an oven at a low temperature, around 150°F or below, for approximately 15 minutes. This process transforms the solid-state into a wax-like consistency. Following this, electrodes are connected to a 12V DC power supply and attached to the cell. The assembly is then carefully placed in a freezer for 15 to 20 minutes, facilitating the charging process. Once removed and disconnected from the power source, the cell is allowed to acclimate to room temperature.
This conditioning process yields a significant increase in voltage, from an initial 1.2V to nearly 2V, illustrating the potential for further enhancements through repeated conditioning. Such advancements suggest the possibility of increasing the cell's efficiency without the necessity of stacking thousands of cells to achieve a higher potential.
This exploration represents a confluence of quantum physics and material science, opening new avenues in energy storage and the development of alternative energy systems. The deliberate creation of a hybrid solid-state electrolyte and dielectric, culminating in the electret effect, underscores the innovative potential of this technology.
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