Skip to main content

Researchers created a holographic wormhole in a quantum computer.



Researchers created a holographic wormhole in a quantum computer. So did they make a wormhole? The answer is yes and no. The holographic wormholes are very weak versions of the wormholes. As I wrote somewhere earlier, the wormhole is not an absolute phenomenon. Its channels across space and time. 

The simulated wormholes show that simulated black holes can exchange information. But exchanging some gravitational waves or electromagnetic wave motion is a little bit different than sending some living animals or even bacteria through that channel. Simulating wormholes can make a revolution in quantum computing. 

Researchers make the simulated black holes by making an electron hole in the 2D atomic structure. Researchers can make Quantum entanglement through those holes. In that case, the energy channel that connects superpositioned and entangled particles will create through two holes linear holes in two opposite 2D structures. Those 2D structures are created by using minimum energy level atoms. 



The measurement accuracy or ability to separate the quantum states in qubits determines the quantum computer's power. So if the system can protect quantum entanglement against outcoming disturbance it allows increased quantum states. And the number of quantum states determines how many parallel lines the quantum computers can use.  

Things like laser rays and other kinds of things can create a so-called "softcore" wormhole that isolates the area from its environment. Or it denies some wavelength of the radiation effect inside the hologram. That thing allows simulation of things that are happening in the real gamma- and gravitational wormholes.

But there is one thing that makes those holographic wormholes interesting. They can protect quantum entanglement against outcoming effects in quantum computers. Hologram wormholes can make it possible to protect the information in light cables, laser communication, and quantum entanglement. 

The hologram or laser ray that is around the light cable or quantum entanglement can deny the outsiders measure the changes in the power of the signals. And that kind of hologram can protect the information in the oscillation circuits. There is the possibility that outsiders can break the communication system by measuring the changes in the electric level in the oscillation circuit. 

If electromagnetic radiation that measurement tool requires hits to the hologram. That system can measure the change in the hologram's energy level. And that thing tells if somebody wants to measure the energy levels in the oscillation circuit. 


https://www.quantamagazine.org/physicists-create-a-wormhole-using-a-quantum-computer-20221130/


https://designandinnovationtales.blogspot.com/


Comments

Popular posts from this blog

Schrödinger's cat: and the limits of that idea.

"In quantum mechanics, Schrödinger's cat is a thought experiment concerning quantum superposition". (Wikipedia, Schrödinger's cat). But the same thing can use as model for many other thought experiments.  Sooner or later, or at least in the ultimate end of the universe, the Schrödinger's cat will turn into wave movement. The information that this cat involved exists but the cat does not exist in its material form. The information doesn't ever vanish. It just turns its shape.  We are all trapped in the universe and time. The universe is the space that is entirety to us. There are no confirmed other universities. But the multiverse is a logical continuum for the expanding galactic megastructures.  The problem with natural things is this. They are black and white. They exist or do not exist. Could there be something, that exists and not exists at the same time?  Scrödinger's cat is thinking experiment about case their cat is not dead or not alive. But in this...

The string theory offers a new way to calculate Pi.

"Scientists discovered a new series for pi through string theory research, echoing a 15th-century formula by Madhava. By combining Euler-Beta Functions and Feynman Diagrams, they modeled particle interactions efficiently. Credit: SciTechDaily.com" (ScitechDaily, String Theory Unravels New Pi Formula: A Quantum Leap in Mathematics) People normally think that. The pi is the ratio of the circumference circle's circumference to the circle's diameter. The Pi is a mathematical constant 3.14159..., the endless decimal number. The Pi is interesting because developers can use that decimal number to make the encryption algorithms stronger.  The idea is that the encryptions program hides the message's original ASCII numbers by multiplicating those numbers with some decimal number. Or the system can add some numbers to those ASCII numbers.  "Aninda Sinha (left) and Arnab Saha (right). Credit: Manu Y" (ScitechDaily, String Theory Unravels New Pi Formula: A Quantum Le...

There are always more than three actors in the real world.

"An international research team is advancing precision timekeeping by developing a nuclear clock using thorium isotopes and innovative laser methods, potentially transforming our understanding of physical constants and dark matter. (Artist’s concept.) Credit: SciTechDaily.com" (ScitechDaily, Unveiling the Thorium Nuclear Clock and Its Time-Twisting Secrets) From Three-body problem... There are no pure three-body systems in nature. There are always more than three components in the system. For making real three-body systems we must separate those three bodies from the environment. Otherwise, there are stable effects. But nobody can predict some effects like distant supernova explosions or sun eruptions.  And one of those things that affect all bodies is time. When radioactive materials decay. That affects the stability and symmetry of the object.  Energy levels affect the existence of things like neutrons. The thorium atom clocks are next-generation tools for time measurement....