The magnetic switch imprisons the patients with quantum information in a dimension
Using chromium sulfide bromide – “miraculous quantum material” – scientists have developed a method for storing quantum information in a single dimension.
Scientists have found how to use quantum material to explore the power of magnetism to Store Quantum Information.
This progress was possible thanks to its ability to chromium sulfure bromide – “Miraculous Material” – capable of supporting magnetic switching.
Study researchers, recently in the Nature Materialsthey theorize that this can lead to a more viable quantum computing and detection, thanks to much more lasting quantum states.
Was used chromium sulfure bromide – An unusual material that has been compared to the thin and folded pasta mass) thanks to its structure of only a few layers of atoms – seen as extremely promising for quantum devices, as many of its properties can be used for any type of information storage.
Advantages of this “bromide”
As it writes, one of the many ways in which chromium sulfure bromide can be used to store information is through excite “Almost particles that form when an electrão and its hole are tied.”
When a photon is moved from its static energy state, it actually leaves behind a hole where it was earlier. Although they are separated, the photon and hole remain paired and become known as excite.
When the chromium sulfure bromide has only one thick atom, the Excits are confined to a single dimension.
When used in a quantum device, this restriction may allow quantum information in exciters to be stored much longer than it would be otherwise, as exciters are less likely to collide with each other and lose information they carry through decoration (loss of quantum information due to interference).
In the new study, the scientists reported that they produced chromium sulfide bromide excitions firing infrared light pulses in 20 gusts lasting only 20 quarters of seconds (20 x 10-15).
Then they used a second infrared laser to push the excitions to a higher state of energy before they found out that they had created Two different variations of excitewhen they should have identical energy states.
When the less energetic pulses were fired by different axle lasers, the researchers found that the direction -dependent excitations could be confined to a single line or expanded in three dimensions.
“The magnetic order is a new adjustment button to shape excitement and their interactions. This can be a revolution for electronics and information technology,” said the study co -author Rupert HuberProfessor of Experimental Physics and Applied at the University of Regensburg, Germany.
