NGF Topp

DuraCotex™ is originally a composite ceramic metal solid. We have managed to let this partially interact with fluoride at high temperature. In stead of regrouping the atoms of the metal the fluoride merely gets between the atoms and weakens the normally strong magnetic structure of the metal, causing the composite to become semi-fluid. The composite keeps most of its metallic features after interacting with the fluoride, except one: It ceases to be a solid.

The fluoride does not react with the metal, so what we've got is free fluor captured between the metal atoms. When exposed to light (< 450nm) we experience quite strong fotoeffect. This rattles the weakened metal bindings in a thin layer of DuraCotex™ allowing the fluoride slowly to escape the composite. At a rate of 120-140 mW/sq.m the fotoeffect will return the composite to its original form - a composite ceramic metal.



The most significant chemical breaktrough is probably the composites ability not to react with the fluoride, even at temperatures where the metal structure is beyond the stabile crystal pattern we are familiar with in ceramic metals. In short what we've got is a piece of metal, which we pack in a tube for you, and you can easily squeze the metal piece out of its tube where it will soon return to a ordinary metallic structure(as shown in picture).

The so called "stickyness" of a normal glue is due to the way it dries when in contact with hi-energy environments like solids, or more spesificly skin. Since any touch will block the light from the glue causing it not to dry, and therefore not stick to your finger. Though whenever exposed to high energy fotons, the glue will become the original composite even between blocking solids.

But even at low IR radiation we will experience a slight fotoeffect in the metal, no more then up to .8 mW/sq.m . But here we clearly see the containment problems of this chemical. DuraCotex™Container is definitely the most significant physical breaktrough with the creation DuraCotex™. Special parabolic reflectors scattered in the plastic tube reflect most of the IR and the silicon plastic takes care of the other radiation. The energy from remaining IR radiation is (in short) induses a currant in wich is used to power the hi-G interactors at the tubes opening, avoiding light from entering through the tubes opening, in other words. Forgetting the cap off the tube wil not be an immediate problem. Further information on the shortrange hi-G is classified by NGF Sales division.

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NGF Topp