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Researchers have discovered a new family of particles in brushes GrafinBase material.
A research group led by Sir Andre Jim and Dr. Alexis Berdigin of the University of Manchester found the new “Brown-Zack Ferms” family online.
The team made this discovery by aligning the bonding of the graphene floor atoms with the heated plates of boron nitrate by dramatically changing the surface properties of the graphite.
The research was carried out after years of supernatural advancements in the Hoffstadter butterfly and today (Friday, November 13, 2020), researchers are reporting another remarkable feature of the structure. Under an applied magnetic field.
Julien Barrier and Dr. “It is known that electrons in the zero magnetic field move in direct orbits and, when applied to a magnetic field, begin to bend and move in a circle. Piranavan Kumaravadiv, who conducted the experiment.
The electrons in the graph layer parallel to the boron nitrate also start to deform, but if you set the magnetic field to a certain value, the electrons will again move in a straight line as if there are no magnetic fields!
Added Dr. The behavior is very different from textbook physics. Piranavan Kumaravadeville’s.
He said this attractive feature would create new brush particles in high magnetic fields. Alexei Berdiogen. Brush particles have special properties and their ability to move even if their magnetic field is very high.
Also published on Regular contactThe work describes how the electrons of the Hoffstadter butterfly fracture function in graphene are encapsulated in the modified skeleton. Over the past decade, improvements in instrumentation and measurement technology have made this work a success.
The concept of brush particles is perhaps one of the most important concepts in situational physics and multicomponent quantum systems. This was discovered in the 1940s by theoretical physicist La Landu, and Julian Barrier described the collective result as a “single particle initiative”. It is used in many complex systems to explain its effects on many parts of the body. “
To date, the general properties of electrons in large-scale graphite networks derive from derivatives of dichotomous particles, which have the unique property of photons repeating in high magnetic fields. However, it does not take into account some of the experimental characteristics of the state, such as further decay or the number of false positives in this case.
The author claims that the “Brown Zach Frames” are a family of brush particles in the supernatural under high magnetic fields. This represents a new quantum quantity that can be directly measured. Interestingly, low temperatures can increase the risk of a reaction at very low temperatures.
When there is a magnetic field, the electrons in the graph start spinning in quantum orbits. For Coffee-Zack Fermion, we were able to recover ten micrometer orbits under magnetic fields up to 16T (about 500,000 times the Earth’s magnetic field). In some cases, the plastic particles they are brushed against do not feel an effective magnetic field. Kumaradeville and Dr. Bardiogen.
In electronic systems, mobility means the ability to move like particles after an electric current has been applied. Since matter provides additional resources (whole and semi-quantum products) and possibly high-frequency transistors, components in “computer processor cores,” the sacred rationale for creating 2D systems such as graphite has long existed.
“We have developed a very clean graphite device for this research,” he said. Kumaradeville. This allows us to achieve a mobility of several million cc, which means that the particles move directly within the device without being distributed. It is important not only for the well-known graphite graphite frames, but also for the brown bags mentioned in this work.
Brown-Zack has created a new playground for superheroes with a fairy bottleneck, identifying not only new metallic minerals common to any super system, but other 2D problems as well.
Julian Barrier adds: “It is clear that this discovery is important for basic electron transport studies, but we believe that understanding brush particles in new super mesh devices under high magnetic fields may lead to the development of new electronic devices.”
High mobility means that transistors made from this device can operate at high frequencies, so processors made from this material can perform more calculations per unit of time, resulting in a faster computer. Typically, applying a magnetic field reduces mobility and allows you to use the device in certain applications. The high mobility of Brown-Zack’s fermion towards high magnetic fields offers a new perspective on dangerous electronic devices.
Reference: 13 November 2020; Regular communication.
I give: 10.1038 / s41467-020-19604-0
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