Breakthrough discovery reveals the particles similar to gravity, showing a specific rotation behavior in a special type of material, called a divided quantitative hall liquid. This discovery of a scientist including Professor Kun Yang of Florida represents a major leap in understanding these unique material states. In the comments published by Professor Yang in innovation, the behavior of these strange particles is similar to the theoretical particles called Gravitons, which are part of some gravity models.
These quantum hall liquids are very attractive because they are disturbed, they maintain abnormal characteristics. However, a key opinion shows that the standard methods of explaining these attributes have missed important geometric elements. This discovery allows researchers to determine the large -scale motion in these liquid structures, and these movements are like vibrations of the material shape. Fascinating is that these vibrations reflect the gravitational behavior, and these particles are considered to be related to gravity.
Through detailed research, the researchers confirmed the existence of these gravitational granules. More importantly, they found their specific rotation behaviors, called manuality. Handicap is a way to rotate in a clockwise or counterclockwise. In this case, the particles show obvious hand -sexual behavior based on the type of liquid they appeared. As Professor Yang explained: “These gravitational particles represent the unique aspects of geometric shapes statement statement statement statement, and thereby provides a new perspective for its complexity.”
When the team led by Professor Yang describes how to detect these particles with specific technologies using polarized light, a major breakthrough occurs. Raman scattering is a process. In the process, light was absorbed and then launched to reveal the energy and spin of these particles. Decades ago, there were no early attempts to capture this behavior due to outdated methods. However, modern tools make it possible. Although the project encountered delays after passing the key researchers, other colleagues continued the work and finally confirmed the existence and behavior of these gravitational granules, and promoted condensing physics and broader gravity research.
This discovery has great significance. This may be observed in the physical system to observe this gravitational particles with specific rotation characteristics. Although the actual gravity related to gravitational waves is still theoretically theoretically, this observation result provides a powerful analogy. The quasi particles are the inspiration names in the material, which is a bit like real particles, but only exists under specific conditions. Most of the quasi particles have simpler characteristics, making a unique rotation discovery particularly important. As Professor Yang emphasized: “These gravitational particles not only happen accidentally. They provide a new method of studying a deeper structure and geometric shape of the quantum hall system.”
The study also provides new ways to study these complex materials. Traditional methods tend to pay attention to the edge of the system. Because of various complex factors, this may be difficult to explain. The new Raman scattering method directly looks at the inside of the material and provides a clearer vision. This method can also help scientists explore certain types of quantitative quantitative subwoings, which may eventually lead to breakthroughs in advanced quantum calculations.
These gravitational particles related to gravity effects are not just metaphors between these gravitational particles and real gravity. Both research areas (with fixed material and gravity) use similar mathematical models, especially when studying less dimensions. Although the “gravity” found in these systems is not the same as the “gravity” predicted by Einstein’s gravity theory, they have enough similarity to encourage more cooperation among scientists in these fields. Yang and his team believe that by further exploring these connections, we can solve new insights on the nature of material and shaping the universe.
This discovery represents the major progress of understanding the complex state, and paved the way for exciting new research opportunities. As scientists continue to study these gravitational particles in depth, we may have a clearer understanding of the basic structure of the universe and their control.
Journal reference
Yang, Kun. “The hand -observed observation of gravity -like stimulation observed in the liquid of the quantity hall.” Innovation, 2024. Doi: https: //doi.org/10.1016/j.xinn.2024.100641
About the author
Dr. Kun Yang (Yang Kun) is a professor of physics at the Florida University and a member of the National High magnetic field laboratory of Tarahaxi, Florida, USA. He obtained a doctorate degree in 1994, and after doctoral work at Princeton University and the California Institute of Technology, he joined the Florida University College in 1999. His research interest is theoretical condensate and statistical physics. The honor and awards he have won over the years include the 1999 Alfred Sloan scholarship, the 2004 Overseas Chinese Physics Association Outstanding Young Researcher Award, and the 2015 Outstanding American Physical Social Judgment Award (APS). Essence In 2011, the 2016 Member of the American Science Development Association (AAAS) in 2016.
In 1989, Dr. Yang Kun went to the United States in the Cuspea project. In 1994, he taught in state universities in 1999. He is currently a lecture professor at McKinqi. He has won the honor of the Sloan Research Award, the Youth Research Award of the Overseas Chinese Institute of Physics, and has been elected as the American Physics Society and the American Science Promotion Association. , And elected the American Physics Society and the American Science Promotion Association.
