Magnetic “Wave Bend” finds that the next generation of communication may be changed

In challenging our understanding of the understanding of wave behavior, researchers at Northeast University showed a new method of using magnetic materials to manipulate sound waves, which may open a new path for classical and quantum communication technology.

The research team cooperated with the Japanese Atomic Energy Bureau and the Ryken Emerging Material Science Center in the Materials Research Institute to observe the unexpected phenomenon: the surface sound waves when the surface sound waves were driving upward, and when the specially designed magnetic grid was driving downwards, the specially designed magnetic grid was driving downward downward. Different behavior.

The role of surface sound waves is similar to the ripple moving on the surface of the pond. It is the basic component in modern communication systems, especially in frequent filters found in the mobile phone. These waves converted the telephoto signal into physical vibration by the process called the piezoelectric effect, thereby achieving effective signal processing.

What makes this discovery particularly interesting is that the team observed the content they called “non -partial shooting diffraction”, which was the phenomenon that I had only seen in the light waves before. Researchers used advanced nano -chemical technology to create accurate magnetic materials at the nano -level, effectively constructing a special grating to make the waves pass.

Yoichi Nii, a researcher participating in the research, pointed out: “This phenomenon was observed in optical components before, so we are very happy to confirm that it beyond the optical range to expand to other wave phenomena.”

The meaning of this discovery exceeds academic interest. The ability to control waves with a magnetic field may lead to more complex acoustic equipment. This may be particularly valuable in quantum computing applications. In the quantum computing application, precise control of wave behavior is essential.

This study fills our understanding of wave physics. Although scientists have a long -term understanding of correction (when driving in the opposite direction, the behavior of wave behavior has different behaviors, this special type of asymmetric diffraction has never been proven in surface sound waves.

Through theoretical modeling, the team traces the asymmetric behavior back to the specific interaction between surface sound waves and magnetic materials, especially related to their angular motion. This understanding can provide new tools for the development of the next -generation communication system.

The timing of this discovery and the industry’s demand for more complicated communication technology has continued to grow. As the current system is close to its physical restrictions, the innovation in wave control and manipulation is becoming increasingly important to improve classical and quantum communication capabilities.

These findings seem to be particularly related to the development of more effective frequency filters and signal processors. These components are essential among all content from smartphones to quantum computers. The ability to accurately control waves with magnetic fields may lead to more efficient and capable equipment than current technology.

This research was published in the “Physics Review Letter” on January 14, 2025, representing an important step in the field of wave physics and material science. With the continuous development of communication technology, such discoveries may be crucial for the next -generation equipment that provides power to the world that we are connected to us.

In the near future, the team plans to explore the actual applications it discovered, especially in the field of quantum engineering. In the field of quantum engineering, precise control of wave behavior can achieve new functions in quantum information processing.