New research from the University of Birmingham examines the properties of photons (individual particles of light) in more detail than ever before.
Ben Yuen and Angela Demetriadou define the precise shape of a single photon. Image credit: Ben Yuen and Angela Demetriadou.
Professor Angela Demetriadou from the University of Birmingham said: “The geometry and optical properties of the environment have a significant impact on how photons are emitted, including defining their shape, color, and even the likelihood of their existence.” said.
The team's new research shows how photons are emitted by atoms and molecules and how they are shaped by their environment.
The nature of this interaction creates endless possibilities for light to exist and propagate, or travel, through the surrounding environment.
However, this infinite possibility makes modeling interactions extremely difficult, a challenge that quantum physicists have been grappling with for decades.
By grouping these possibilities into distinct sets, the authors explain not only the interaction between the photon and the emitter, but also how the energy from that interaction is transmitted far into the far field. I was able to create a model.
At the same time, they were able to use calculations to visualize the photons themselves.
“Our calculations have enabled us to transform a seemingly unsolvable problem into a computable problem,” said Dr. Benjamin Yuen from the University of Birmingham.
“And almost as a byproduct of the model, we were able to generate this image of a photon that physics had never seen before.”
This research is important because it opens new research avenues for quantum physicists and materials scientists.
Being able to precisely define how photons interact with matter and other elements of its environment allows scientists to discover ways to communicate securely, detect pathogens, control chemical reactions at the molecular level, and more. We can design new nanophotonics technologies that have the potential to change the world.
“This research will help us better understand the energy exchange between light and matter, which in turn will help us better understand how light radiates into nearby and distant environments,” Yuen said. Ta.
“A lot of this information used to be thought of as just noise, but there is so much information in it that we can now understand and use. .”
“By understanding this, we have established a foundation from which we can engineer light-matter interactions for future applications such as better sensors, improved photovoltaic cells, and quantum computing.”
of work Published in a magazine physical review letter.
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Ben Yuen and Angela Demetriadou. 2024. Precise quantum electrodynamics of synchrotron radiation environments. Physics. pastor rhett 133, 203604; doi: 10.1103/PhysRevLett.133.203604
Source: www.sci.news
