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In accordance with the appropriate spacing and torsion angle, a first high-molecular material, a second high-molecular material, and a third high-molecular material are stacked, weaved, heated, sized, rolled, cooled, and solidified to make a quantum stealth material.
The invention also includes a method for making a quantum stealth material, which is difficult to detect by optical, infrared, and electromagnetic detection devices and has good shielding properties against optical, infrared, and electromagnetic waves. The quantum stealth material is also unaffected by geographic environments, climatic conditions, and other objective factors.
Additionally, the quantum stealth material, which has the advantages of an easy preparation procedure and strong product stability, is frequently used in stealth technology scenarios involving the detection of optical, infrared, and electromagnetic waves that are bent.
The first macromolecular material, the second macromolecular material, and the third macromolecular material make up a type of quantum stealth material.
The first macromolecular material is vertically symmetrically distributed in the second macromolecular material on both sides and forms a hollow channel, the second macromolecule material and the third macromolecular material are in the horizontal direction according to corresponding windup-degree tilt distribution, and the process is laminated braiding, heat-shaping, rolling through rolling apparatus, cool and solidify, and then form.
The Global quantum stealth market accounted for $XX Billion in 2023 and is anticipated to reach $XX Billion by 2030, registering a CAGR of XX% from 2024 to 2030.
A Canadian business named Hyperstealth that specializes in camouflage design has invented the newest invisibility technology, known as Quantum Stealth. It costs little money, is powerless, and is as thin as paper. Even if it doesn’t conceal as well as a magical cloak, it nevertheless does a respectable job and is certainly perplexing to look at.
The method used in the content is lenticular lenses, which you may already be familiar with. You have probably seen this technology if you have seen one of those images that, depending on how you look at it, looks to be 3D.
Similar to how it bends light, the material can make it so that only objects up close or extremely far away are visible. As a result, everything or everyone placed behind it at a given distance will vanish. The substance can bend light from the mid- and near-ultraviolet to the infrared, and it has a rather large bandwidth.
When the substance is examined with cameras that operate outside of the visible light spectrum, the effect is much more pronounced and stunning due to their reduced resolution. Although the specifics are plainly classified, the physics is surprisingly simple. The rule is referred to as Snell’s law.
Each substance has a unique refractive index, which is a measurement of the difference between the speed of light in that material and the speed of light in a vacuum.
