Skip to main content

The new nanoscale nodes are making the quantum radar possible.

 

.

The new nanoscale nodes are making the quantum radar possible.

(Image I) "THIS ILLUSTRATION OF A NANOSCALE NODE CREATED BY THE LAB OF NICK VAMIVAKAS, PROFESSOR OF QUANTUM OPTICS AND QUANTUM PHYSICS, SHOWS A CLOSEUP OF ONE OF AN ARRAY PILLARS, EACH A MERE 120 NANOMETERS HIGH. EACH PILLAR SERVES AS A LOCATION MARKER FOR A QUANTUM STATE THAT CAN INTERACT WITH PHOTONS.

A NOVEL ALIGNMENT OF TUNGSTEN DISELENIDE (WSE2) IS DRAPED OVER THE PILLARS WITH AN UNDERLYING, HIGHLY REACTIVE LAYER OF CHROMIUM TRIIODIDE (CRI3). WHERE THE ATOMICALLY THIN, 12-MICRON AREA LAYERS TOUCH, THE CRI3 IMPARTS AN ELECTRIC CHARGE TO THE WSE2, CREATING A “HOLE” ALONGSIDE EACH OF THE PILLARS. CREDIT: UNIVERSITY OF ROCHESTER ILLUSTRATION / MICHAEL OSADCIW" ( SciTechDaily)

The new nanoscale nodes are making the quantum radar possible.

The idea of stealth hacking is theoretically simple.

1) The nanoscale nodes are making it possible to hack the stealth materials

The stealth material that is looking like pyramids would light with the radio rays, which are jumping back from the bottom of the canyons between those pyramids. But the fact is that the radar rays must be extremely tight, that it doesn't cause the disturbing radio turbulence if it jumps from the walls of the structure. Also, the time of the impulses must be so short, that the echoes of the walls of the "canyon" would cause minimum radio turbulence for those radio rays, which are like pikes when they are hitting the material.

But the counter radiation can turn that radiation away from the layer. The stealth hack is possible, but it works only with the limited scale of stealth materials. The stealth plane is not immune to anti-stealth radars, but they are still hard to detect.

2) The extremely long wavelength can make the straight radio waves possible, and that technology can make some stealth planes visible.

Above this text is the image of nano-size nodes, which can send so-called straight radar signals. Those signals can hack the stealth core of the most modern stealth planes. Hacking the stealth can be done by using radio waves, which have an extremely long wavelength. That wavelength causes that radio impulses would go in the middle of the triangular structures of stealth material. Making this kind of system is theoretically easy, but practical solutions are more difficult than we even think.

And that thing causes the radar echo. The problem with hacking the stealth structure is that the structure itself is probably acting that it will make the radio impulses jumping between layers, which are like a V-shape canyon.

One version of stealth hacking uses the high-flying radar planes, which radar looks down. That means that stealth aircraft is looking like a shadow over the ground.

3) Bombing the target by using the high power electrons or some other electromagnetic radiation can hack the stealth structure.

The idea is that the radar will send the high-energetic electrons to the target. Those electrons would cause that the stealth plane will start to send the radio waves. The high-energy radiation would simply make the radio resonance to structure. That should turn the stealth plane into a radio transmitter. But the problem is that those electrons can turn away by pointing them with counter radiation.

The lidar or laser radars can same way scan the suspected area, and that radiation causes the heating of the stealth plane. And even if the system cannot see the stealth itself by using laser echoes, that system can turn the stealth visible by heating it, and in those cases, the infrared system can detect the stealth plane.

The problem with stealth material is that if they are just absorbing electromagnetic radiation, that thing causes overheating. So the energy must conduct to somewhere like the capacitor, which would deny the overheating of the structure.

4) Plasma radar is a more conventional version of quantum radars.

Quantum radar is one of the most fascinating tools in the world. The ability to detect the stealth aircraft or stealth structure requires the new type of radars and another version of the quantum radars is the plasma radar, where the detection of target bases the movement of plasma. The plasma is acting like an ionized atom in the scanning tunneling microscope and makes it possible to see a stealth plane.

And that means the radar cannot see the target itself, but the implied detection is always possible. In this case, the radar sees the movements of the gas around the target. So the detection is happening by using the medium, and the movement of the plasma is causing the detection. The system follows the radar echoes from the plasma field, and that makes the stealth plane observable.

Image I: https://scitechdaily.com/building-a-quantum-network-using-tiny-nanoscale-nodes/

https://curiosityanddarkmatter.home.blog/2020/12/27/the-new-nanoscale-nodes-are-making-the-quantum-radar-possible/

Comments

Post a Comment

Popular posts from this blog

Plasmonic waves can make new waves in quantum technology.

"LSU researchers have made a significant discovery related to the fundamental properties and behavior of plasmonic waves, which can lead ot the development of more sensitive and robust quantum technologies. Credit: LSU" (ScitechDaily, Plasmonics Breakthrough Unleashes New Era of Quantum Technologies) Plasmonic waves in the quantum gas are the next-generation tools. The plasmonic wave is quite similar to radio waves. Or, rather say it, a combination of acoustic waves and electromagnetic waves. Quantum gas is an atom group. In those atom groups, temperature and pressure are extremely low.  The distance of atoms is long. And when an electromagnetic system can pump energy to those atoms. But the thing in quantum gas is that the atoms also make physical movements like soundwaves. It's possible. To create quantum gas using monoatomic ions like ionized noble gas. In those systems, positive (or negative) atoms push each other away.  When the box is filled with quantum gas and som
Post a Comment
Read more

The breakthrough in solid-state qubits.

Hybrid integration of a designer nanodiamond with photonic circuits via ring resonators. Credit Steven Burrows/Sun Group (ScitechDaily, Solid-State Qubits: Artificial Atoms Unlock Quantum Computing Breakthrough) ****************************************** The next part is from ScitechDaily.com "JILA breakthrough in integrating artificial atoms with photonic circuits advances quantum computing efficiency and scalability". (ScitechDaily, Solid-State Qubits: Artificial Atoms Unlock Quantum Computing Breakthrough) "In quantum information science, many particles can act as “bits,” from individual atoms to photons. At JILA, researchers utilize these bits as “qubits,” storing and processing quantum 1s or 0s through a unique system". (ScitechDaily, Solid-State Qubits: Artificial Atoms Unlock Quantum Computing Breakthrough) "While many JILA Fellows focus on qubits found in nature, such as atoms and ions, JILA Associate Fellow and University of Colorado Boulder Assistant
Post a Comment
Read more

Metamaterials can change their properties in an electric- or electro-optical field.

"Researchers have created a novel metamaterial that can dynamically tune its shape and properties in real-time, offering unprecedented adaptability for applications in robotics and smart materials. This development bridges the gap between current materials and the adaptability seen in nature, paving the way for the future of adaptive technologies. Credit: UNIST" (ScitechDaily, Metamaterial Magic: Scientists Develop New Material That Can Dynamically Tune Its Shape and Mechanical Properties in Real-Time) Metamaterials can change their properties in an electric- or electro-optical field.  An electro-optical activator can also be an IR state, which means. The metamorphosis in the material can thermally activate.  AI is the ultimate tool for metamaterial research. Metamaterials are nanotechnical- or quantum technical tools that can change their properties, like reflection or state from solid to liquid when the electric or optical effect hits that material. The metamaterial can cru
Post a Comment
Read more