C R Y S T A L A M N I U M
OUT OF CHARACTER INFORMATION
Intent: To create a new component for starship construction.
Image Source: Munkhjin Otogonbayar (x) (x) (x)
Primary Source: Trilamnium (x) Laminanium (x)
Name: Crystalaminum
Manufacturer: Primo Victorian (x)
Affiliation: Primo Victorian, Closed-Market | Contract Thread Required
Homeworld (optional): N/A
Production: Minor
Modularity: None
Material:
Molytex
Quantum Fiber
Reinforced Duraplast
Neutronium
Crystadurium
Agrinium
Laminasteel
Trimantium
PHYSICAL SPECIFICATIONS
Classification: Compound
Weight: Average
Resistances:
Blasters/Other Plasma: High
Kinetic: High
Lightsabers: High
EMP/Ion: Average
Corrosion: Very Low
Elemental: Average
[*]
Color: Blue / Black / Silver Steel
SPECIAL FEATURES
A compound highly resistant to blaster/turbolaser fire.
Utilizes the strengths of reinforced duraplast, molytex, and quantum fiber.
Constructed with a lattice base, with a neutronium center for ultra-dispersive characteristics.
Uses crystadurium to disperse heat, uses laminasteel and trimantium for reinforced high tensile strength.
Agrinium presents to aid in the handling of electromagnetic radiation.
Blasters and Turbolasers: Built to withstand the heat of great magnitudes the compound is highly resistant to blasters and other types of plasma weaponry such as turbolasers.
Kinetic: Thanks to both lattice structure and components within the compound it is also able to withstand a high amount of kinetic damage.
EMP/Ion: While given an average rating for EMP/Ion radiation, it does so with more efficiency at the inner layers than outside. Therefore overtime emp/ion weaponry have a greater chance of affecting the compound.
Corrosion: Greatly affected by corrosion, the compound, is unable to withstand the corrosive power of acidic attacks, or other corrosion attacks.
After the development of Crystaplast, Fiolette turned her attention to creating a Trilamnium like compound. She took a sample of the compound and took it apart in her office and examined the structure under a microscope. She then turned and compared it to laminanium’s components she wrote down the base structures of both and went to the labs.
Fiolette realized that by using some of the same materials from the crystaplast and adding elements from Taeli’s Trilamnium and Laminanium in order to improve the compound’s ability to absorb and disperse heat.
Utilizing a fine lattice structure, each layer of material would be rotated slightly. This allows the materials to absorb kinetic damage at greater efficiency. The shock from kinetic impact/damage would be unable to penetrate all the layers at once. The materials are also better able to disperse the heat of a blaster/turbolaser or even an emp/ion blast as the lattice structure would take far more energy to heat up considerably.
In similar fashion, to Crystaplast the neutronium sits in the center with layers of crystadurium and reinforced duraplast on either side. Additional layers include molytex and quantum fiber which are woven on top of each other in a tight crisscross pattern. These woven layers are then rotated slightly to form the lattice structure. The same reinforced duraplast-agrinium sheets from Crystaplast is then embedded into the top layers of laminasteel and trimantium to aid in the handling of electromagnetic radiation.
Overall the process and formation of the lattice structure proved to be the key to the compound. Followed by the components of the Crystalamnium layered in their particular order. Fiolette then turned to produce the component on a trial run for smaller ships, before green-lighting the production as the main hull component in larger ships.
