John Locke
V U L K A N
SPECIAL FEATURES
DESCRIPTION
Born from the crucible of deep research into Vajra-based alloys and Stygian-triprismatic polymers, Chimei represents the cutting edge of quantum material science. Designed in response to the limitations of prior stealth and energy-conductive materials, Chimei is an advanced hybrid alloy that combines the room-temperature superconductivity of Ultrachrome and Vajra with the adaptive stealth characteristics of Stygian-triprismatic composites. The result? A material that doesn't just perform—it adapts, evades, and evolves under pressure.
At its core, Chimei is a room-temperature superconductor, transmitting electrical current across its surface with zero resistance and no energy loss. This property alone makes it ideal for power transmission, advanced capacitors, and perpetual energy loops in closed systems. However, what sets Chimei apart is its Unstable Electron Matrix, a quantum phenomenon that allows the flow of electricity across the material to be dynamically re-routed at a molecular level. This instability allows for on-demand generation of ultra-thin circuits and electromagnets, real-time adaptive resistance control, and hyper-sensitive electromagnetic detection. Chimei doesn't just conduct electricity—it thinks with it.
But Chimei's technological edge doesn't stop at conductivity. Its stealth capabilities redefine the battlefield. By merging the stealth-dampening properties of Stygian-triprismatic polymer with the quantum behavior of Vajra, Chimei can vanish from most conventional and advanced sensor arrays. It not only absorbs and redirects sound and radiation—it can control the signal profile it returns, projecting false data to enemy scanners and mimicking everything from mundane starship hull plating to empty space. Whether used in cloaking systems, sensor-dampening coatings, or infiltration tech, Chimei doesn't just hide—it misleads.
Like its predecessors, Chimei is not a defensive material—it was never designed for combat armor. Its structural integrity is adequate for embedded systems, but it performs poorly under direct kinetic or energy-based assault. Additionally, its quantum electron matrix can be destabilized by exposure to more powerful electromagnetic forces than its host system is generating. This vulnerability can disrupt its electromagnets, degrade signal control, and compromise its circuit configurations mid-use.
In essence, Chimei is not a hammer—it is a scalpel. A precision-engineered material designed for stealth ships, sensor-baffling devices, next-gen computers, and flexible energy systems. In the right hands, it is a ghost in the machine. In the wrong hands... a phantom you'll never see coming.
- Superconductor
- Unstable Electron Matrix
- Stealth capability
- Superconductor:
- Like Ultrachrome and Vajra, Chimei is a room temperature superconductor. This means it is able to transmit electrical energy across it's surface with no resistance and therefore no energy loss. This means that if electricity was passed into a loop of Chimei, it could run indefinately, until the circuit was broken, making Vajra an efficient material for the transfer of energy and for use in electromagnets
- Unstable Electron Matrix
- Vajra is a quantum material, and as such the electrons in it's structure are in a state of instability. These fluctuations have a number of benefits which make Vajra an incredibly versatile material.
- Due to the instability of electrons within the metal's structure the path of electrical currents across the surface can be routed and rerouted at will allowing control of resistances and the flow of current at a molecular level. This has a variety of uses in computing and electromagnetism.
- The instability of electrons in the material makes it sensitive to electromagnetic radiation, allowing it to be used as a sensor.
- With the correct stimuli the electrons in the material can be adjusted, allowing the creation of molecular thick electromagnets and circuits.
- Vajra is a quantum material, and as such the electrons in it's structure are in a state of instability. These fluctuations have a number of benefits which make Vajra an incredibly versatile material.
- Stealthy
- Chimei is an ally of Vajra and Stygian-triprismatic polymer, taking the best elements of both into a superior material. While it retains the super conductivity and unstable electron matrix that make Vajra so useful, it also carries with it the Stygian-triprismatic polymer's stealth capabilities. Like it's precedant, it is capable of both improving stealth fields and dampening sound, byt the addition of the Unstable Electron Matrix to the material allows it to control the radiation which reflects back from it. Chimei is capable of vanishing from sensors, or sending back sensor returns which make it appear as something else.
- Not armour:
- Like both Vajra and Stygian-triprismatic polymer Chimei is no a powerful defensive material, and fares badly in direct combat.
- A more powerful force
- If the Chimei is subjected to a more powerful electromagnetic force than the one that it's user is generating that can disrupt any circuits and magnets it has formed as well as altering the resistive capabilities of the material.
Born from the crucible of deep research into Vajra-based alloys and Stygian-triprismatic polymers, Chimei represents the cutting edge of quantum material science. Designed in response to the limitations of prior stealth and energy-conductive materials, Chimei is an advanced hybrid alloy that combines the room-temperature superconductivity of Ultrachrome and Vajra with the adaptive stealth characteristics of Stygian-triprismatic composites. The result? A material that doesn't just perform—it adapts, evades, and evolves under pressure.
At its core, Chimei is a room-temperature superconductor, transmitting electrical current across its surface with zero resistance and no energy loss. This property alone makes it ideal for power transmission, advanced capacitors, and perpetual energy loops in closed systems. However, what sets Chimei apart is its Unstable Electron Matrix, a quantum phenomenon that allows the flow of electricity across the material to be dynamically re-routed at a molecular level. This instability allows for on-demand generation of ultra-thin circuits and electromagnets, real-time adaptive resistance control, and hyper-sensitive electromagnetic detection. Chimei doesn't just conduct electricity—it thinks with it.
But Chimei's technological edge doesn't stop at conductivity. Its stealth capabilities redefine the battlefield. By merging the stealth-dampening properties of Stygian-triprismatic polymer with the quantum behavior of Vajra, Chimei can vanish from most conventional and advanced sensor arrays. It not only absorbs and redirects sound and radiation—it can control the signal profile it returns, projecting false data to enemy scanners and mimicking everything from mundane starship hull plating to empty space. Whether used in cloaking systems, sensor-dampening coatings, or infiltration tech, Chimei doesn't just hide—it misleads.
Like its predecessors, Chimei is not a defensive material—it was never designed for combat armor. Its structural integrity is adequate for embedded systems, but it performs poorly under direct kinetic or energy-based assault. Additionally, its quantum electron matrix can be destabilized by exposure to more powerful electromagnetic forces than its host system is generating. This vulnerability can disrupt its electromagnets, degrade signal control, and compromise its circuit configurations mid-use.
In essence, Chimei is not a hammer—it is a scalpel. A precision-engineered material designed for stealth ships, sensor-baffling devices, next-gen computers, and flexible energy systems. In the right hands, it is a ghost in the machine. In the wrong hands... a phantom you'll never see coming.
Out Of Character Info
Intent:
To sub a specialised, stealth focused material to be used in future submissions.
Primary Source(s):
Technical Information
Affiliation:
Locke and Key Mechanics
Model:
Chimei
Modular:
No
Material:
Vajra | Stygian-triprismatic polymer
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