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| 2024 | Lóng Lóng |
| 2019 | Stalacite |
The ĀrSalx Electrophysiological Integration and Future Energy Management Model
As shown in the image, these are mutated salmon eggs from the Narmuth region—ĀrSalx. Their ancestors once thrived in the irradiated zone of Seraz, where large-scale energy extraction and nuclear radiation leaks led to ecological mutations. The radiation profoundly altered the aquatic environment, causing the salmon’s scales to evolve nanoscale metallic particle structures composed of titanium, nickel, and molybdenum. These particles are arranged on the surface of the scales in pyramid-like microscopic geometries. This specific arrangement allows the scales to automatically adjust their functions under different radiation wavelengths: when environmental temperatures drop, the scales absorb radiation energy and store it in tiny reservoirs within the scales; when temperatures rise, the nanostructures on the scales reflect excess heat, preventing overheating.
On a genetic level, radiation triggered mutations in their internal organs. The gills and liver evolved into complex “chemical reactor” organs. A unique protein in the gills breaks down toxic gases in the air, converting them into usable energy molecules. The liver, through a series of electrochemical reactions, transforms heavy metals and harmful substances into electricity, which is stored in battery-like cells and transmitted via the nervous system to support the salmon’s physiological functions.
As the environment shifted, the ancestors of ĀrSalx began migrating toward volcanic regions, a perilous journey filled with underwater fissures releasing toxic gases and frequent earthquakes. The salmon developed a group behavior, communicating through chemical signals and magnetic field sensing to maintain tight formations. Specific lead individuals in each group would sense geomagnetic shifts and guide the group away from volcanic eruptions or underwater fissures. These leaders marked their migration paths with chemical signals secreted from their gills, ensuring the group’s safe navigation through dangerous territories.
Around the volcano, some of the eggs were covered by lava and gradually petrified over thousands of years due to geological changes. The high levels of silicates and iron oxides in the lava seeped into the eggshells and reacted with the carbon-based material inside, slowly transforming these eggs into mineral fossils. This petrification process occurred under extreme heat and pressure, taking millennia. Meanwhile, another portion of the eggs evolved under these extreme conditions. Their cellular structure gradually shifted from a carbon-based form to a semi-energy, semi-matter state. The new life forms developed a photoelectric nervous system, where their internal neural network, akin to optical fibers, transmitted highly efficient photoelectric pulses.
These pulses were used not only for energy transmission but also for information exchange. Their bodies became semi-transparent, with the pulses flickering inside like electrical currents flowing through a living organism. They survived by absorbing geothermal energy from the volcanic environment and chemical substances from the ocean floor. The frequency and intensity of these pulses directly influenced their behavior and interaction with the environment, enabling them to adjust the electromagnetic field around them to adapt to extreme conditions. These eggs carried the societal legacy of Elvārth. The microstructures within them stored fragments of past civilizations’ culture, abandoned technological codes, and records of ecological shifts. Their evolutionary trajectory reflected the rise and fall of societies, with one key element being the lost knowledge of energy conversion technology from the Narmuth region.
These new life forms could break species barriers and engage in interspecies hybridization. ĀrSalx conducted energy exchanges through their photoelectric nervous systems and integrated genetic information from other species via resonating photoelectric pulses. This resonance mechanism depended on specific environmental factors, such as strong geomagnetic fields or high radiation levels. Through this process, ĀrSalx could fuse with volcanic microorganisms or subterranean fungi, creating new hybrid life forms. For instance, some “salmon-fungi” hybrids used the fungal root systems to penetrate deep into the earth, absorbing minerals, while the salmon component relied on its photoelectric system to gather energy from the surface and regulate energy flow.
These “salmon-fungi” hybrids played a crucial role in their ecosystems. The fungal roots secreted chemicals that regulated soil composition, providing a more favorable energy environment for the salmon. The salmon, in turn, sensed environmental changes in radiation and temperature through its photoelectric pulses, automatically adjusting the surrounding electromagnetic field to help the entire hybrid survive in extreme conditions. This symbiotic structure functioned like an ecological fortress, capable of self-sustenance in hostile environments.
ĀrSalx plays a crucial role in the abandoned ruins of the Narmuth civilization. When they approach the end of their life cycle, their photoelectric nervous system triggers a series of reactions that gradually transform their biological tissue into a pure energy form. This process occurs under extreme conditions, such as high temperatures, intense radiation, or energy depletion. The photoelectric energy stored within their cells is activated, breaking down the cellular structure and releasing protons, electrons, and photons in the form of electromagnetic waves. This energy doesn’t fully dissipate but instead concentrates into a “photoelectric field,” where the core energy of ĀrSalx is preserved. If the surrounding environment contains sufficient energy, ĀrSalx can reconstitute its material form by absorbing external energy, achieving resurrection. This rebirth process resembles the reorganization of energy from the photoelectric field into a biological structure, granting a form of “immortality.”
Humans discovered this property and applied it to the restoration of the Narmuth ruins. ĀrSalx has precise repair capabilities, using high-frequency pulses from its photoelectric nervous system to scan ancient electronic devices. These pulses detect breaks or shorts in circuits and repair them with micro amounts of photoelectric energy.
ĀrSalx can sense weak energy fluctuations in its environment, similar to biological electromagnetic detection, and trace the flow of energy. Its photoelectric pulses “read” these fluctuations, identifying the source and path of residual energy, and by adjusting its pulse frequency, it can reactivate dormant energy channels. If the energy is insufficient, ĀrSalx draws radiation or geothermal energy from the environment, converting it into usable electricity to sustain the energy network, keeping ancient systems operational. Humans not only used ĀrSalx to restore old technological systems but also integrated its energy systems into new structures of civilization, making ĀrSalx a driving force in the rebuilding of civilization from the technological ruins.
Gumi Lu/ˈɡuː.mi/
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