yurian_lattice_plasma
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yurian_lattice_plasma [2018/01/19 16:24] conan image crediting |
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| - | ===== Yurian Lattice Plasma ===== | + | ====== Yurian Lattice Plasma ====== |
| [[https://commons.wikimedia.org/wiki/File:Long_exposure_of_plasma_globe.jpg|{{https://upload.wikimedia.org/wikipedia/commons/thumb/a/ae/Long_exposure_of_plasma_globe.jpg/800px-Long_exposure_of_plasma_globe.jpg?300 }}]] | [[https://commons.wikimedia.org/wiki/File:Long_exposure_of_plasma_globe.jpg|{{https://upload.wikimedia.org/wikipedia/commons/thumb/a/ae/Long_exposure_of_plasma_globe.jpg/800px-Long_exposure_of_plasma_globe.jpg?300 }}]] | ||
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| [{{ https://upload.wikimedia.org/wikipedia/commons/a/ab/Lightning8_-_NOAA.jpg?100|Lightning creates natural plasma by ionizing air}}] | [{{ https://upload.wikimedia.org/wikipedia/commons/a/ab/Lightning8_-_NOAA.jpg?100|Lightning creates natural plasma by ionizing air}}] | ||
| - | === Formation === | + | ==== Formation ==== |
| It is not currently known precisely how Yurian Lattice Plasma stabilises in nature, but it is generally found temporarily occupying areas with a strong magnetic field, usually in the lower atmosphere of planets with a rotating liquid metal core. It is thought to require the complex interaction between a magnetic field, atmospheric gases and nearby resonant metalliferous minerals. The current natural formation hypothesis is when a plasma, formed by lightning or similar striking a mineral-rich deposit, loses energy to the environment while in a strong magnetic field. During its cooling, a lattice forms as an elevated "trough" state, which stabilised the plasma and allows it to retain energy for much longer than normal. | It is not currently known precisely how Yurian Lattice Plasma stabilises in nature, but it is generally found temporarily occupying areas with a strong magnetic field, usually in the lower atmosphere of planets with a rotating liquid metal core. It is thought to require the complex interaction between a magnetic field, atmospheric gases and nearby resonant metalliferous minerals. The current natural formation hypothesis is when a plasma, formed by lightning or similar striking a mineral-rich deposit, loses energy to the environment while in a strong magnetic field. During its cooling, a lattice forms as an elevated "trough" state, which stabilised the plasma and allows it to retain energy for much longer than normal. | ||
| - | === Decay === | + | ==== Decay ==== |
| Outside of vacuum-sealed magnetic containment, the lattice does decay from the outside in due to interaction with non-ionized particles in the environment. A lattice exposed to atmosphere will typically last a few hours at most, although this period can be extended by the maintenance of the magnetic field that produced the lattice in the first place. | Outside of vacuum-sealed magnetic containment, the lattice does decay from the outside in due to interaction with non-ionized particles in the environment. A lattice exposed to atmosphere will typically last a few hours at most, although this period can be extended by the maintenance of the magnetic field that produced the lattice in the first place. | ||
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| If captured in vacuum bound by a magnetic field, Yurian Lattice Plasma can persist almost indefinitely. This aspect, combined with its effect on electromagnetic energy storage systems, is what makes this rare substance so useful. | If captured in vacuum bound by a magnetic field, Yurian Lattice Plasma can persist almost indefinitely. This aspect, combined with its effect on electromagnetic energy storage systems, is what makes this rare substance so useful. | ||
| - | ==== Applications ==== | + | ===== Applications ===== |
| Many high-energy storage systems such as [[Charge Pack|charge packs]] currently hold power in the form of energetic plasmas. Yurian Lattice Plasma is able to retain usable power at much lower energy states than ordinary plasmas without dissapating. When an energetic plasma energy strage system is filled with Yurian Lattice Plasma, the stabilising effect of the lattice allows it to hold far more usable energy than would normally be possible. | Many high-energy storage systems such as [[Charge Pack|charge packs]] currently hold power in the form of energetic plasmas. Yurian Lattice Plasma is able to retain usable power at much lower energy states than ordinary plasmas without dissapating. When an energetic plasma energy strage system is filled with Yurian Lattice Plasma, the stabilising effect of the lattice allows it to hold far more usable energy than would normally be possible. | ||
yurian_lattice_plasma.txt ยท Last modified: 2024/04/22 22:56 by conan
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