What Is Quantum Reflex Analysis?

Quantum reflection ( Quantum reflection ) is a physical phenomenon describing the reflection of material waves from gravitational potential. This phenomenon is impossible in classical physics. For example, when one magnet is attracted by another magnet, one of the magnets does not suddenly reverse and the other one pushes away. [1]

Quantum reflection became the 21st century
in spite of
(1) Use the transfer matrix method (ATMM) to obtain accurate transmission and reflection coefficients, and apply it to the problem of quantum reflection above the barrier height. By calculating the step exponential decay barrier and the squared barrier, it is found that the results obtained with ATMM are more accurate than those obtained with WKB approximation. When the incident energy of the particles is higher than the barrier height, ATMM can still draw accurate conclusions; WKB cannot do anything about it. The calculation results show that the reflectivity is a gradual process, indicating that quantum reflection has occurred, and ATMM can be used to solve this kind of problem. [2]
(2) Two independent groups of scientists have built the thinnest mirror in the world: MoSe2 pieces, each of which is monoatomic. Mirrors were developed at Harvard University and at the same time as quantum electronics at the Zurich Institute, and researchers say these engineering expertise push the limits of what is possible in this physical world. Although close to the minimum thickness that an object may have under the law of objects and maintaining reflection, tiny mirrors reflect a lot of light. The first paper said that a Harvard mirror mounted on a silicon substrate reflected 85% of the light. Swiss research shows that Zurich mirrors mounted on silicon dioxide (a type of silicon oxide) reflect 41 percent. The light reflected by both mirrors is in the 780 nanometer range, deep red. MoSe2 acts as a mirror because electrons have a very specific way around the nucleus. As previously described in a paper published in September 2017, this substance tends to form voids in its electron field-the area where electrons can orbit without electrons. Smashing a photon or light particle into an atom gives the electron a chance to jump from a low-energy orbit to a high-energy orbit. Once this happens, a void called an "electron hole" is formed in the electronic field. The electrons surrounding MoSe2 are particularly likely to behave in this manner when illuminated with light of certain wavelengths. Electrons are negatively charged quantum objects. The protons in the nucleus are positively charged. So, this is a tricky problem. Those electron holes will take away some positive charges from the protons in the nucleus. This makes these holes behave a bit like particles, although they do have no particles. Nearby, negatively charged electrons attract those fake particles, and in some cases pair with them to form strange quantum mechanical objects called excitons. Those excitons emit their own light, interfere with the incident light, and send it back, just like a mirror in a bathroom. These ultra-thin mirrors have a lot of real-world potential. Optoelectronic Engineers-People working on miniature optical chips, fiber optic networks, and other equipment that rely on tightly controlled small photon beams can benefit from even ordinary one-atom-wide mirrors.

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